(K Subramanya) Engineering Hydrology - PDFCOFFEE.COM (2024)

THIRD EDITION

About the Author Dr K Subramanya is a retired Professor of Civil Engineering at the Indian Institute of Technology, Kanpur. He obtained his bachelor’s degree in Civil Engineering from Mysore University and a master’s degree from the University of Madras. Further, he obtained another master’s degree and Ph. D from the University of Alberta, Edmonton, Canada. He has taught at IIT Kanpur for over 30 years and has extensive teaching experience in the area of Hydrology and Water Resources Engineering. During his tenure at IIT Kanpur, Prof. Subramanya worked as Visiting Faculty at the Asian Institute of Technology, Bangkok, for a short while. He has authored several successful books for McGraw-Hill Education (India). Besides the current book, his other books include Flow in Open Channels (2nd Ed., TMH, 1997), and 1000 Solved Problems in Fluid Mechanics (TMH, 2005). Dr Subramanya has published over eighty technical papers in national and international journals. He has also presented numerous technical papers in conferences. He is a Fellow of the Institution of Engineers (India); Fellow of Indian Society for Hydraulics; Member of Indian Society of Technical Education and Member of Indian Water Resources Association. Currently, he resides in Bangalore and is active as a practicing consultant in Water Resources Engineering. He can be contacted at [emailprotected].

THIRD EDITION

K Subramanya Former Professor of Civil Engineering Indian Institute of Technology Kanpur

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Dedicated to My Mother

Contents

Preface to the Third Edition Preface to the First Edition 1. Introduction 1.1 Introduction 1 1.2 Hydrologic Cycle 1 1.3 Water Budget Equation 3 1.4 World Water Balance 6 1.5 History of Hydrology 8 1.6 Applications in Engineering 9 1.7 Sources of Data 10 References 11 Revision Questions 11 Problems 11 Objective Questions 12

xiii xv 1

2. Precipitation 2.1 Introduction 13 2.2 Forms of Precipitation 13 2.3 Weather Systems for Precipitation 14 2.4 Characteristics of Precipitation in India 16 2.5 Measurement of Precipitation 20 2.6 Raingauge Network 24 2.7 Preparation of Data 26 2.8 Presentation of Rainfall Data 30 2.9 Mean Precipitation Over an Area 33 2.10 Depth-Area-Duration Relationships 37 2.11 Frequency of Point Rainfall 39 2.12 Maximum Intensity-Duration-Frequency Relationship 43 2.13 Probable Maximum Precipitation (PMP) 48 2.14 Rainfall Data in India 50 References 51 Revision Questions 51 Problems 51 Objective Questions 56

13

3. Abstractions from Precipitation 3.1 Introduction 59 3.2 Evaporation Process 59

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3.3 Evaporimeters 60 3.4 Empirical Evaporation Equations 63 3.5 Analytical Methods of Evaporation Estimation 64 3.6 Reservoir Evaporation and Methods for its Reduction 66 3.7 Transpiration 68 3.8 Evapotranspiration 69 3.9 Measurement of Evapotranspiration 70 3.10 Evapotranspiration Equations 70 3.11 Potential Evapotranspiration Over India 76 3.12 Actual Evapotranspiration (AET) 76 3.13 Interception 79 3.14 Depression Storage 79 3.15 Infiltration 80 3.16 Infiltration Capacity 81 3.17 Measurement of Infiltration 82 3.18 Modeling Infiltration Capacity 84 3.19 Classification of Infiltration Capacities 91 3.20 Infiltration Indices 92 References 95 Revision Questions 96 Problems 96 Objective Questions 99 4. Streamflow Measurement 4.1 Introduction 101 4.2 Measurement of Stage 102 4.3 Measurement of Velocity 105 4.4 Area-Velocity Method 109 4.5 Dilution Technique of Streamflow Measurement 113 4.6 Electromagnetic Method 115 4.7 Ultrasonic Method 116 4.8 Indirect Methods 117 4.9 Stage-Discharge Relationship 122 4.10 Extrapolation of Rating Curve 129 4.11 Hydrometry Stations 131 References 133 Revision Questions 133 Problems 134 Objective Questions 137

101

5. Runoff 5.1 Introduction 139 5.2 Hydrograph 141 5.3 Runoff Characteristics of Streams 142 5.4 Runoff Volume 143 5.5 Flow-Duration Curve 163

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5.6 Flow-Mass Curve 166 5.7 Sequent Peak Algorithm 171 5.8 Droughts 175 5.9 Surface Water Resources of India 182 References 187 Revision Questions 187 Problems 188 Objective Questions 192 6. Hydrographs 6.1 Introduction 195 6.2 Factors Affecting Flood Hydrograph 196 6.3 Components of a Hydrograph 198 6.4 Base Flow Separation 202 6.5 Effective Rainfall (ER) 203 6.6 Unit Hydrograph 205 6.7 Derivation of Unit Hydrographs 212 6.8 Unit Hydrographs of Different Durations 216 6.9 Use and Limitations of Unit Hydrograph 223 6.10 Duration of the Unit Hydrograph 223 6.11 Distribution Graph 224 6.12 Synthetic Unit Hydrograph 225 6.13 Instantaneous Unit Hydrograph (IUH) 232 References 235 Revision Questions 235 Problems 237 Objective Questions 242

195

7. Floods 7.1 Introduction 245 7.2 Rational Method 245 7.3 Empirical Formulae 251 7.4 Unit Hydrograph Method 253 7.5 Flood Frequency Studies 253 7.6 Gumbel’s Method 255 7.7 Log-Pearson Type III Distribution 263 7.8 Partial Duration Series 266 7.9 Regional Flood Frequency Analysis 266 7.10 Data for Frequency Studies 266 7.11 Design Flood 267 7.12 Design Storm 269 7.13 Risk, Reliability and Safety Factor 271 References 273 Revision Questions 273 Problems 274 Objective Questions 278

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8. Flood Routing 8.1 Introduction 280 8.2 Basic Equations 281 8.3 Hydrologic Storage Routing (Level Pool Routing) 281 8.4 Attenuation 290 8.5 Hydrologic Channel Routing 291 8.6 Hydraulic Method of Flood Routing 296 8.7 Routing in Conceptual Hydrograph Development 297 8.8 Clark’s Method for IUH 298 8.9 Nash’s Conceptual Model 301 8.10 Flood Control 309 8.11 Flood Control in India 313 References 314 Revision Questions 314 Problems 315 Objective Questions 318

280

9. Groundwater 9.1 Introduction 320 9.2 Forms of Subsurface Water 320 9.3 Aquifer Properties 323 9.4 Geologic Formations as Aquifers 330 9.5 Compressibility of Aquifers 330 9.6 Equation of Motion 333 9.7 Wells 343 9.8 Steady Flow into a Well 344 9.9 Open Wells 349 9.10 Unsteady Flow in a Confined Aquifer 351 9.11 Well Loss 356 9.12 Specific Capacity 357 9.13 Recharge 357 9.14 Groundwater Resource 361 9.15 Groundwater Monitoring Network in India 365 References 366 Revision Questions 366 Problems 367 Objective Questions 371

320

10. Erosion and Reservoir Sedimentation 10.1 Introduction 374 10.2 Erosion Processes 374 10.3 Estimation of Sheet Erosion 376 10.4 Channel Erosion 379 10.5 Movement of Sediment from Watersheds 381 10.6 Sediment Yield from Watersheds 382

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10.7 Trap Efficiency 386 10.8 Density of Sediment Deposits 388 10.9 Distribution of Sediment in the Reservoir 391 10.10 Life of a Reservoir 400 10.11 Reservoir Sedimentation Control 403 10.12 Erosion and Reservoir Sedimentation Problems in India 405 References 407 Revision Questions 409 Problems 409 Objective Questions 412 Appendix A: Additonal References, Some Useful Websites, Abbreviations

413

Appendix B: Conversion Factors

416

Answers to Objective Questions

417

Index

428

Chapter

1

INTRODUCTION

1.1 INTRODUCTION Hydrology means the science of water. It is the science that deals with the occurrence, circulation and distribution of water of the earth and earth’s atmosphere. As a branch of earth science, it is concerned with the water in streams and lakes, rainfall and snowfall, snow and ice on the land and water occurring below the earth’s surface in the pores of the soil and rocks. In a general sense, hydrology is a very broad subject of an inter-disciplinary nature drawing support from allied sciences, such as meteorology, geology, statistics, chemistry, physics and fluid mechanics. Hydrology is basically an applied science. To further emphasise the degree of applicability, the subject is sometimes classified as 1. Scientific hydrology—the study which is concerned chiefly with academic aspects. 2. Engineering or applied hydrology—a study concerned with engineering applications. In a general sense engineering hydrology deals with (i) estimation of water resources, (ii) the study of processes such as precipitation, runoff, evapotranspiration and their interaction and (iii) the study of problems such as floods and droughts, and strategies to combat them. This book is an elementary treatment of engineering hydrology with descriptions that aid in a qualitative appreciation and techniques which enable a quantitative evaluation of the hydrologic processes that are of importance to a civil engineer.

1.2

HYDROLOGIC CYCLE

Water occurs on the earth in all its three states, viz. liquid, solid and gaseous, and in various degrees of motion. Evaporation of water from water bodies such as oceans and lakes, formation and movement of clouds, rain and snowfall, streamflow and groundwater movement are some examples of the dynamic aspects of water. The various aspects of water related to the earth can be explained in terms of a cycle known as the hydrologic cycle. Figure 1.1 is a schematic representation of the hydrologic cycle. A convenient starting point to describe the cycle is in the oceans. Water in the oceans evaporate due to the heat energy provided by solar radiation. The water vapour moves upwards and forms clouds. While much of the clouds condense and fall back to the oceans as rain, a part of the clouds is driven to the land areas by winds. There they condense and precipitate onto the land mass as rain, snow, hail, sleet, etc. A part of the precipitation

Engineering Hydrology

Fig. 1.1

The Hydrologic Cycle

may evaporate back to the atmosphere even while falling. Another part may be intercepted by vegetation, structures and other such surface modifications from which it may be either evaporated back to atmosphere or move down to the ground surface. A portion of the water that reaches the ground enters the earth’s surface through infiltration, enhance the moisture content of the soil and reach the groundwater body. Vegetation sends a portion of the water from under the ground surface back to the atmosphere through the process of transpiration. The precipitation reaching the ground surface after meeting the needs of infiltration and evaporation moves down the natural slope over the surface and through a network of gullies, streams and rivers to reach the ocean. The groundwater may come to the surface through springs and other outlets after spending a considerably longer time than the surface flow. The portion of the precipitation which by a variety of paths above and below the surface of the earth reaches the stream channel is called runoff. Once it enters a stream channel, runoff becomes stream flow. The sequence of events as above is a simplistic picture of a very complex cycle that has been taking place since the formation of the earth. It is seen that the hydrologic cycle is a very vast and complicated cycle in which there are a large number of paths of varying time scales. Further, it is a continuous recirculating cycle in the sense that there is neither a beginning nor an end or a pause. Each path of the hydrologic cycle involves one or more of the following aspects: (i) transportation of water, (ii) temporary storage and (iii) change of state. For example, (a) the process of rainfall has the

Introduction

!

change of state and transportation and (b) the groundwater path has storage and transportation aspects. The main components of the hydrologic cycle can be broadly classified as transportation ( flow) components and storage components as below: Transportation components Precipitation Evaporation Transpiration Infiltration Runoff

Storage components Storage on the land surface (Depression storage, Ponds, Lakes, Reservoirs, etc) Soil moisture storage Groundwater storage

Schematically the interdependency of the transportation components can be represented as in Fig. 1.2. The quantities of water going through various individual paths of the hydrological cycle in a given system can be described by the continuity principle known as water budget equation or hydrologic equation. It is important to note that the total water resources of the earth Fig. 1.2 Transportation Components of the are constant and the sun is the Hydrologic Cycle source of energy for the hydrologic cycle. A recognition of the various processes such as evaporation, precipitation and groundwater flow helps one to study the science of hydrology in a systematic way. Also, one realises that man can interfere with virtually any part of the hydrologic cycle, e.g. through artificial rain, evaporation suppression, change of vegetal cover and land use, extraction of groundwater, etc. Interference at one stage can cause serious repercussions at some other stage of the cycle. The hydrological cycle has important influences in a variety of fields including agriculture, forestry, geography, economics, sociology and political scene. Engineering applications of the knowledge of the hydrologic cycle, and hence of the subjects of hydrology, are found in the design and operation of projects dealing with water supply, irrigation and drainage, water power, flood control, navigation, coastal works, salinity control and recreational uses of water.

1.3 WATER BUDGET EQUATION Catchment Area The area of land draining into a stream or a water course at a given location is known as catchment area. It is also called as drainage area or drainage basin. In USA, it is known as watershed. A catchment area is separated form its neighbouring areas by a

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Engineering Hydrology

ridge called divide in USA and watershed in UK (Fig. 1.3). The areal extent of the catchment is obtained by tracing the ridge on a topographic map to delineate the catchment and measuring the area by a planimeter. It is obvious that for a river while mentioning the catchment area the station to which it pertains (Fig. 1.3) must also be mentioned. It is normal to assume the groundwater divide to coincide with the surface divide. Thus, the Fig. 1.3 Schematic Sketch of Catchment catchment area affords a logical and of River A at Station M convenient unit to study various aspects relating to the hydrology and water resources of a region. Further it is probably the singlemost important drainage characteristic used in hydrological analysis and design.

Water Budget Equation For a given problem area, say a catchment, in an interval of time Dt, the continuity equation for water in its various phases is written as Mass inflow – mass outflow = change in mass storage If the density of the inflow, outflow and storage volumes are the same Vi - V0 = DS (1.1) where Vi = inflow volume of water into the problem area during the time period, V0 = outflow volume of water from the problem area during the time period, and DS = change in the storage of the water volume over and under the given area during the given period. In applying this continuity equation [Eq. (1.1)] to the paths of the hydrologic cycle involving change of state, the volumes considered are the equivalent volumes of water at a reference temperature. In hydrologic calculations, the volumes are often expressed as average depths over the catchment area. Thus, for example, if the annual stream flow from a 10 km2 catchment is 107 m3, it corresponds to a depth of æ 107 ö çè 10 ´ 106 ÷ø = 1 m = 100 cm. Rainfall, evaporation and often runoff volumes are expressed in units of depth over the catchment. While realizing that all the terms in a hydrological water budget may not be known to the same degree of accuracy, an expression for the water budget of a catchment for a time interval Dt is written as P – R – G – E – T = DS (1.2-a) In this P = precipitation, R = surface runoff, G = net groundwater flow out of the catchment, E = evaporation, T = transpiration and DS = change in storage. The storage S consists of three components as S = Ss + Ssm + Sg where Ss = surface water storage Ssm = water in storage as soil moisture and Sg = water in storage as groundwater.

Introduction

#

Thus in Eq. (1.2-a) DS = DSs + DSsm + DSg All terms in Eq. (1.2-a) have the dimensions of volume. Note that all these terms can be expressed as depth over the catchment area (e.g. in centimetres), and in fact this is a very common unit. In terms of rainfall–runoff relationship, Eq. (1.2-a) can be represented as R=P–L (1.2-b) where L = Losses = water not available to runoff due to infiltration (causing addition to soil moisture and groundwater storage), evaporation, transpiration and surface storage. Details of various components of the water budget equation are discussed in subsequent chapters. Note that in Eqs (1.2-a and b) the net import of water into the catchment, from sources outside the catchment, by action of man is assumed to be zero. EXAMPLE 1.1 A lake had a water surface elevation of 103.200 m above datum at the beginning of a certain month. In that month the lake received an average inflow of 6.0 m3/s from surface runoff sources. In the same period the outflow from the lake had an average value of 6.5 m3/s. Further, in that month, the lake received a rainfall of 145 mm and the evaporation from the lake surface was estimated as 6.10 cm. Write the water budget equation for the lake and calculate the water surface elevation of the lake at the end of the month. The average lake surface area can be taken as 5000 ha. Assume that there is no contribution to or from the groundwater storage. SOLUTION: In a time interval D t the water budget for the lake can be written as Input volume – output volume = change in storage of the lake

( I Dt + PA) – ( Q Dt + EA) = DS where I = average rate of inflow of water into the lake, Q = average rate of outflow from the lake, P = precipitation, E = evaporation, A = average surface area of the lake and D S = change in storage volume of the lake. Here D t = 1 month = 30 ´ 24 ´ 60 ´ 60 = 2.592 ´ 106 s = 2.592 Ms In one month: Inflow volume = I Dt = 6.0 ´ 2.592 = 15.552 M m3 Outflow volume = Q Dt = 6.5 ´ 2.592 = 16.848 M m3 Input due to precipitation = PA =

14.5 ´ 5000 ´ 100 ´ 100 100 ´ 10 6

M m3 = 7.25 M m3

6.10 5000 ´ 100 ´ 100 ´ = 3.05 M m3 100 106 DS = 15.552 + 7.25 – 16.848 – 3.05 = 2.904 M m3

Outflow due to evaporation = EA = Hence

2.904 ´ 106 DS = 0.058 m = A 5000 ´ 100 ´ 100 New water surface elevation at the end of the month = 103.200 + 0.058 = 103.258 m above the datum.

Change in elevation

Dz =

EXAMPLE 1.2 A small catchment of area 150 ha received a rainfall of 10.5 cm in 90 minutes due to a storm. At the outlet of the catchment, the stream draining the catchment was dry before the storm and experienced a runoff lasting for 10 hours with an average discharge of 1.5 m3/s. The stream was again dry after the runoff event. (a) What is the amount of water which was not available to runoff due to combined effect of infiltration, evaporation and transpiration? What is the ratio of runoff to precipitation?

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Engineering Hydrology

SOLUTION: The water budget equation for the catchment in a time D t is

R=P–L (1.2-b) where L = Losses = water not available to runoff due to infiltration (causing addition to soil moisture and groundwater storage), evaporation, transpiration and surface storage. In the present case Dt = duration of the runoff = 10 hours. Note that the rainfall occurred in the first 90 minutes and the rest 8.5 hours the precipitation was zero. (a) P = Input due to precipitation in 10 hours = 150 ´ 100 ´ 100 ´ (10.5/100) = 157,500 m3 R = runoff volume = outflow volume at the catchment outlet in 10 hours = 1.5 ´ 10 ´ 60 ´ 60 = 54,000 m3 Hence losses L = 157,500 – 54,000 = 103,500 m3 (b) Runoff/rainfall = 54,000/157,500 = 0.343 (This ratio is known as runoff coefficient and is discussed in Chapter 5)

1.4 WORLD WATER BALANCE The total quantity of water in the world is estimated to be about 1386 million cubic kilometres (M km3). About 96.5% of this water is contained in the oceans as saline water. Some of the water on the land amounting to about 1% of the total water is also saline. Thus only about 35.0 M km3 of fresh water is available. Out of this about 10.6 M km3 is both liquid and fresh and the remaining 24.4 M km3 is contained in frozen state as ice in the polar regions and on mountain tops and glaciers. An estimated distribution of water on the earth is given in Table 1.1. Table 1.1

Estimated World Water Quantities

Item

Area (M km2)

Volume (M km3)

1. Oceans 2. Groundwater (a) fresh (b) saline 3. Soil moisture 4. Polar ice 5. Other ice and snow 6. Lakes (a) fresh (b) saline 7. Marshes 8. Rivers 9. Biological water 10. Atmospheric water

361.3

1338.0

Total: (a) All kinds of water (b) Fresh water

510.0 148.8

134.8 134.8 82.0 16.0 0.3 1.2 0.8 2.7 148.8 510.0 510.0

10.530 12.870 0.0165 24.0235 0.3406 0.0910 0.0854 0.01147 0.00212 0.00112 0.01290 1386.0 35.0

Percent Percent total water fresh water 96.5

—

0.76 0.93 0.0012 1.7 0.025

30.1 — 0.05 68.6 1.0

0.007 0.006 0.0008 0.0002 0.0001 0.001

0.26 — 0.03 0.006 0.003 0.04

100.0 2.5

100.0

Table from WORLD WATER BALANCE AND WATER RESOURCES OF THE EARTH, © UNESCO, 1975. Reproduced by the permission of UNESCO.

Introduction

%

The global annual water balance is shown in Table 1.2. Table 1.2 Item 2

1. Area (M km ) 2. Precipitation (km3/year) (mm/year) 3. Evaporation (km3/year) (mm/year) 4. Runoff to ocean (i) Rivers (km3/year) (ii) Groundwater (km3/year) Total Runoff (km3/year) (mm/year)

Global Annual Water Balance Ocean

Land

361.30 458,000 1270 505,000 1400

148.8 119,000 800 72,000 484 44,700 2,200 47,000 316

Table from WORLD WATER BALANCE AND WATER RESOURCES OF THE EARTH, © UNESCO, 1975. Reproduced by the permission of UNESCO.

It is seen from Table 1.2 that the annual evaporation from the world’s oceans and inland areas are 0.505 and 0.072 M km3 respectively. Thus, over the oceans about 9% more water evaporates than that falls back as precipitation. Correspondingly, there will be excess precipitation over evaporation on the land mass. The differential, which is estimated to be about 0.047 M km3 is the runoff from land mass to oceans and groundwater outflow to oceans. It is interesting to know that less than 4% of this total river flow is used for irrigation and the rest flows down to sea. These estimates are only approximate and the results from different studies vary; the chief cause being the difficulty in obtaining adequate and reliable data on a global scale. The volume in various phases of the hydrologic cycle (Table 1.1) as also the rate of flow in that phase (Table 1.2) do vary considerably. The average duration of a particle of water to pass through a phase of the hydrologic cycle is known as the residence time of that phase. It could be calculated by dividing the volume of water in the phase by the average flow rate in that phase. For example, by assuming that all the surface runoff to the oceans comes from the rivers, From Table 1.1, the volume of water in the rivers of the world = 0.00212 M km3 From Table 1.2, the average flow rate of water in global rivers = 44700 km3/year Hence residence time of global rivers, Tr = 2120/44700 = 0.0474 year = 17.3 days. Similarly, the residence time for other phases of the hydrological cycle can be calculated (Prob. 1.6). It will be found that the value of Tr varies from phase to phase. In a general sense the shorter the residence time the greater is the difficulty in predicting the behaviour of that phase of the hydrologic cycle. Annual water balance studies of the sub-areas of the world indicate interesting facts. The water balance of the continental land mass is shown in Table 1.3(a). It is interesting to see from this table that Africa, in spite of its equatorial forest zones, is

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Engineering Hydrology

the driest continent in the world with only 20% of the precipitation going as runoff. On the other hand, North America and Europe emerge as continents with highest runoff. Extending this type of analysis to a smaller land mass, viz. the Indian subcontinent, the long term average runoff for India is found to be 46%. Table 1.3(a) Water Balance of Continents2 mm/year Continent Africa Asia Australia Europe N. America S. America

Area Precipitation (M km2) 30.3 45.0 8.7 9.8 20.7 17.8

686 726 736 734 670 1648

Total runoff

Runoff as % of precipitation

Evaporation

139 293 226 319 287 583

20 40 30 43 43 35

547 433 510 415 383 1065

Water balance studies on the oceans indicate that there is considerable transfer of water between the oceans and the evaporation and precipitation values vary from one ocean to another (Table 1.3(b)). Table 1.3(b) Water Balance of Oceans2 mm/year Ocean

Atlantic Arctic Indian Pacific

Area Precipitation (M km2) 107 12 75 167

780 240 1010 1210

Inflow from adjacent continents 200 230 70 60

Evaporation

1040 120 1380 1140

Water exchange with other oceans –60 350 –300 130

Each year the rivers of the world discharge about 44,700 km3 of water into the oceans. This amounts to an annual average flow of 1.417 Mm3/s. The world’s largest river, the Amazon, has an annual average discharge of 200,000 m3/s, i.e. one-seventh of the world’s annual average value. India’s largest river, the Brahmaputra, and the second largest, the Ganga, flow into the Bay of Bengal with a mean annual average discharges of 16,200 m3/s and 15,600 m3/s respectively.

1.5 HISTORY OF HYDROLOGY Water is the prime requirement for the existence of life and thus it has been man’s endeavour from time immemorial to utilise the available water resources. History has instances of civilizations that flourished with the availability of dependable water supplies and then collapsed when the water supply failed. Numerous references exist in Vedic literature to groundwater availability and its utility. During 3000 BC groundwater development through wells was known to the people of the Indus Valley civilizations as revealed by archaeological excavations at Mohenjodaro. Quotations in ancient Hindu scriptures indicate the existence of the knowledge of the hydrologic cycle even as far back as the Vedic period. The first description of the raingauge and its use is contained

Introduction

'

in the Arthashastra by Chanakya (300 BC). Varahamihira’s (AD 505–587) Brihatsamhita contains descriptions of the raingauge, wind vane and prediction procedures for rainfall. Egyptians knew the importance of the stage measurement of rivers and records of the stages of the Nile dating back to 1800 BC have been located. The knowledge of the hydrologic cycle came to be known to Europe much later, around AD 1500. Chow1 classifies the history of hydrology into eight periods as: 1. Period of speculation—prior to AD 1400 2. Period of observation—1400–1600 3. Period of measurement—1600–1700 4. Period of experimentation—1700–1800 5. Period of modernization—1800–1900 6. Period of empiricism—1900–1930 7. Period of rationalization—1930–1950 8. Period of theorization—1950–to–date Most of the present-day science of hydrology has been developed since 1930, thus giving hydrology the status of a young science. The worldwide activities in waterresources development since the last few decades by both developed and developing countries aided by rapid advances in instrumentation for data acquisition and in the computer facilities for data analysis have contributed towards the rapid growth rate of this young science.

1.6 APPLICATIONS IN ENGINEERING Hydrology finds its greatest application in the design and operation of water-resources engineering projects, such as those for (i) irrigation, (ii) water supply, (iii) flood control, (iv) water power, and (v) navigation. In all these projects hydrological investigations for the proper assessment of the following factors are necessary: 1. The capacity of storage structures such as reservoirs. 2. The magnitude of flood flows to enable safe disposal of the excess flow. 3. The minimum flow and quantity of flow available at various seasons. 4. The interaction of the flood wave and hydraulic structures, such as levees, reservoirs, barrages and bridges. The hydrological study of a project should necessarily precede structural and other detailed design studies. It involves the collection of relevant data and analysis of the data by applying the principles and theories of hydrology to seek solutions to practical problems. Many important projects in the past have failed due to improper assessment of the hydrological factors. Some typical failures of hydraulic structures are: (i) overtopping and consequent failure of an earthen dam due to an inadequate spillway capacity, (ii) failure of bridges and culverts due to excess flood flow and (iii) inability of a large reservoir to fill up with water due to overestimation of the stream flow. Such failure, often called hydrologic failures underscore the uncertainty aspect inherent in hydrological studies.

Engineering Hydrology

Various phases of the hydrological cycle, such as rainfall, runoff, evaporation and transpiration are all nonuniformly distributed both in time and space. Further, practically all hydrologic phenomena are complex and at the present level of knowledge, they can at best be interpreted with the aid of probability concepts. Hydrological events are treated as random processes and the historical data relating to the event are analysed by statistical methods to obtain information on probabilities of occurrence of various events. The probability analysis of hydrologic data is an important component of present-day hydrological studies and enables the engineer to take suitable design decisions consistent with economic and other criteria to be taken in a given project.

1.7 SOURCES OF DATA Depending upon the problem at hand, a hydrologist would require data relating to the various relevant phases of the hydrological cycle playing on the problem catchment. The data normally required in the studies are: l Weather records—temperature, humidity and wind velocity l Precipitation data l Stream flow records l Evaporation and evapotranspiration data l Infiltration characteristics of the study area l Soils of the area l Land use and land cover l Groundwater characteristics l Physical and geological characteristics of the area l Water quality data In India, hydro-meteorological data are collected by the India Meteorological Department (IMD) and by some state government agencies. The Central Water Commission (CWC) monitors flow in major rivers of the country. Stream flow data of various rivers and streams are usually available from the State Water Resources/Irrigation Department. Groundwater data will normally be available with Central Groundwater Board (CGWB) and state Government groundwater development agencies. Data relating evapotranspiration and infiltration characteristics of soils will be available with State Government organizations such as Department of Agriculture, Department of Watershed development and Irrigation department. The physical features of the study area have to be obtained from a study of topographical maps available with the Survey of India. The information relating to geological characteristics of the basin under study will be available with the Geological Survey of India and the state Geology Directorate. Information relating to soils at an area are available from relevant maps of National Bureau of Soil Survey and Land Use Planning (NBSS&LUP), 1996. Further additional or specific data can be obtained from the state Agriculture Department and the state Watershed Development Department. Land use and land cover data would generally be available from state Remote sensing Agencies. Specific details will have to be derived through interpretation of multi-spectral multi-season satellite images available from National Remote Sensing Agency (NRSA) of Government of India. Central and State Pollution Control Boards, CWC and CGWB collect water quality data.

Introduction

REFERENCES 1. Chow, V.T., (Ed), Handbook of Applied Hydrology, McGraw-Hill, New York, NY, 1964. 2. Schendel, V., “The world’s water resources and water balance”, Natural Resources and Development, Vol. 1, 1975, Inst. for Sci. Coop, Hannover, Germany, pp. 8–14. 3. UNESCO, “World Water Balance and Water Resources of the Earth”, Studies and Reports in Hydrology, 25, UNESCO, Paris, France, 1978. 4. Van der Leeden, Water Resources of the World, Water Information Center, Port Washington, N.Y., USA, 1975.

REVISION QUESTIONS 1.1 Describe the Hydrologic cycle. Explain briefly the man’s interference in various parts of this cycle. 1.2 Discuss the hydrological water budget with the aid of examples. 1.3 What are the significant features of global water balance studies? 1.4 List the major activities in which hydrological studies are important. 1.5 Describe briefly the sources of hydrological data in India.

PROBLEMS

1.1 Two and half centimetres of rain per day over an area of 200 km2 is equivalent to average rate of input of how many cubic metres per second of water to that area? 1.2 A catchment area of 140 km2 received 120 cm of rainfall in a year. At the outlet of the catchment the flow in the stream draining the catchment was found to have an average rate of 2.0 m3/s for 3 months, 3.0 m3/s for 6 months and 5.0 m3/s for 3 months. (i) What is the runoff coefficient of the catchment? (ii) If the afforestation of the catchment reduces the runoff coefficient to 0.50, what is the increase in the abstraction from precipitation due to infiltration, evaporation and transpiration, for the same annual rainfall of 120 cm? 1.3 Estimate the constant rate of withdrawal from a 1375 ha reservoir in a month of 30 days during which the reservoir level dropped by 0.75 m in spite of an average inflow into the reservoir of 0.5 Mm3/day. During the month the average seepage loss from the reservoir was 2.5 cm, total precipitation on the reservoir was 18.5 cm and the total evaporation was 9.5 cm. 1.4 A river reach had a flood wave passing through it. At a given instant the storage of water in the reach was estimated as 15.5 ha.m. What would be the storage in the reach after an interval of 3 hours if the average inflow and outflow during the time period are 14.2 m3/ s and 10.6 m3/s respectively? 1.5 A catchment has four sub-areas. The annual precipitation and evaporation from each of the sub-areas are given below. Assume that there is no change in the groundwater storage on an annual basis and calculate for the whole catchment the values of annual average (i) precipitation, and (ii) evaporation. What are the annual runoff coefficients for the sub-areas and for the total catchment taken as a whole? Sub-area

Area Mm2

Annual precipitation mm

Annual evaporation mm

A B C D

10.7 3.0 8.2 17.0

1030 830 900 1300

530 438 430 600

Engineering Hydrology

1.6 Estimate the residence time of (a) Global atmospheric moisture. (b) Global groundwater by assuming that only the fresh groundwater runs off to the oceans. (c) Ocean water.

OBJECTIVE QUESTIONS 1.1 The percentage of earth covered by oceans is about (a) 31% (b) 51% (c) 71% (d) 97% 1.2 The percentage of total quantity of water in the world that is saline is about (a) 71% (b) 33% (c) 67% (d) 97% 1.3 The percentage of total quantity of fresh water in the world available in the liquid form is about (a) 30% (b) 70% (c) 11% (d) 51% 1.4 If the average annual rainfall and evaporation over land masses and oceans of the earth are considered it would be found that (a) over the land mass the annual evaporation is the same as the annual precipitation (b) about 9% more water evaporates from the oceans than what falls back on them as precipitation (c) over the ocean about 19% more rain falls than what is evaporated (d) over the oceans about 19% more water evaporates than what falls back on them as precipitation. 1.5 Considering the ratio of annual precipitation to runoff = r0 for all the continents on the earth, (a) Asia has the largest value of the ratio r0. (b) Europe has the smallest value of r0. (c) Africa has the smallest value of r0. (d) Australia has the smallest value of r0. 1.6 In the hydrological cycle the average residence time of water in the global (a) atmospheric moisture is larger than that in the global rivers (b) oceans is smaller than that of the global groundwater (c) rivers is larger than that of the global groundwater (d) oceans is larger than that of the global groundwater. 1.7 A watershed has an area of 300 ha. Due to a 10 cm rainfall event over the watershed a stream flow is generated and at the outlet of the watershed it lasts for 10 hours. Assuming a runoff/rainfall ratio of 0.20 for this event, the average stream flow rate at the outlet in this period of 10 hours is (a) 1.33 m3/s (b) 16.7 m3/s (c) 100 m3/minute (d) 60,000 m3/h 1.8 Rainfall of intensity of 20 mm/h occurred over a watershed of area 100 ha for a duration of 6 h. measured direct runoff volume in the stream draining the watershed was found to be 30,000 m3. The precipitation not available to runoff in this case is (a) 9 cm (b) 3 cm (c) 17.5 mm (d) 5 mm 1.9 A catchment of area 120 km2 has three distinct zones as below: Zone

Area (km2)

Annual runoff (cm)

A B C

61 39 20

52 42 32

The annual runoff from the catchment, is (a) 126.0 cm (b) 42.0 cm (c) 45.4 cm

(d) 47.3 cm

Chapter

2

PRECIPITATION

2.1 INTRODUCTION The term precipitation denotes all forms of water that reach the earth from the atmosphere. The usual forms are rainfall, snowfall, hail, frost and dew. Of all these, only the first two contribute significant amounts of water. Rainfall being the predominant form of precipitation causing stream flow, especially the flood flow in a majority of rivers in India, unless otherwise stated the term rainfall is used in this book synonymously with precipitation. The magnitude of precipitation varies with time and space. Differences in the magnitude of rainfall in various parts of a country at a given time and variations of rainfall at a place in various seasons of the year are obvious and need no elaboration. It is this variation that is responsible for many hydrological problems, such as floods and droughts. The study of precipitation forms a major portion of the subject of hydrometeorology. In this chapter, a brief introduction is given to familiarize the engineer with important aspects of rainfall, and, in particular, with the collection and analysis of rainfall data. For precipitation to form: (i) the atmosphere must have moisture, (ii) there must be sufficient nuclei present to aid condensation, (iii) weather conditions must be good for condensation of water vapour to take place, and (iv) the products of condensation must reach the earth. Under proper weather conditions, the water vapour condenses over nuclei to form tiny water droplets of sizes less than 0.1 mm in diameter. The nuclei are usually salt particles or products of combustion and are normally available in plenty. Wind speed facilitates the movement of clouds while its turbulence retains the water droplets in suspension. Water droplets in a cloud are somewhat similar to the particles in a colloidal suspension. Precipitation results when water droplets come together and coalesce to form larger drops that can drop down. A considerable part of this precipitation gets evaporated back to the atmosphere. The net precipitation at a place and its form depend upon a number of meteorological factors, such as the weather elements like wind, temperature, humidity and pressure in the volume region enclosing the clouds and the ground surface at the given place.

2.2 FORMS OF PRECIPITATION Some of the common forms of precipitation are: rain, snow, drizzle, glaze, sleet and hail. Rain It is the principal form of precipitation in India. The term rainfall is used to describe precipitations in the form of water drops of sizes larger than 0.5 mm. The maximum size of a raindrop is about 6 mm. Any drop larger in size than this tends to

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Engineering Hydrology

break up into drops of smaller sizes during its fall from the clouds. On the basis of its intensity, rainfall is classified as: Type 1. Light rain 2. Moderate rain 3. Heavy rain

Intensity trace to 2.5 mm/h 2.5 mm/h to 7.5 mm/h > 7.5 mm/h

Snow Snow is another important form of precipitation. Snow consists of ice crystals which usually combine to form flakes. When fresh, snow has an initial density varying from 0.06 to 0.15 g/cm3 and it is usual to assume an average density of 0.1 g/ cm3. In India, snow occurs only in the Himalayan regions. Drizzle A fine sprinkle of numerous water droplets of size less than 0.5 mm and intensity less than 1 mm/h is known as drizzle. In this the drops are so small that they appear to float in the air. Glaze When rain or drizzle comes in contact with cold ground at around 0º C, the water drops freeze to form an ice coating called glaze or freezing rain. Sleet It is frozen raindrops of transparent grains which form when rain falls through air at subfreezing temperature. In Britain, sleet denotes precipitation of snow and rain simultaneously. Hail It is a showery precipitation in the form of irregular pellets or lumps of ice of size more than 8 mm. Hails occur in violent thunderstorms in which vertical currents are very strong.

2.3 WEATHER SYSTEMS FOR PRECIPITATION For the formation of clouds and subsequent precipitation, it is necessary that the moist air masses cool to form condensation. This is normally accomplished by adiabatic cooling of moist air through a process of being lifted to higher altitudes. Some of the terms and processes connected with the weather systems associated with precipitation are given below. Front A front is the interface between two distinct air masses. Under certain favourable conditions when a warm air mass and cold air mass meet, the warmer air mass is lifted over the colder one with the formation of a front. The ascending warmer air cools adiabatically with the consequent formation of clouds and precipitation. Cyclone A cyclone is a large low pressure region with circular wind motion. Two types of cyclones are recognised: tropical cyclones and extratropical cyclones. Tropical cyclone: A tropical cyclone, also called cyclone in India, hurricane in USA and typhoon in South-East Asia, is a wind system with an intensely strong depression with MSL pressures sometimes below 915 mbars The normal areal extent of a cyclone is about 100–200 km in diameter. The isobars are closely spaced and the winds are anticlockwise in the northern hemisphere. The centre of the storm, called the eye, which may extend to about 10–50 km in diameter, will be relatively quiet. However, right outside the eye, very strong winds/reaching to as much as 200 kmph

Precipitation

#

exist. The wind speed gradually decreases towards the outer edge. The pressure also increases outwards (Fig. 2.1). The rainfall will normally be heavy in the entire area occupied by the cyclone.

Fig. 2.1 Schematic Section of a Tropical Cyclone During summer months, tropical cyclones originate in the open ocean at around 5– 10° latitude and move at speeds of about 10–30 kmph to higher latitudes in an irregular path. They derive their energy from the latent heat of condensation of ocean water vapour and increase in size as they move on oceans. When they move on land the source of energy is cut off and the cyclone dissipates its energy very fast. Hence, the intensity of the storm decreases rapidly. Tropical cyclones cause heavy damage to life and property on their land path and intense rainfall and heavy floods in streams are its usual consequences. Tropical cyclones give moderate to excessive precipitation over very large areas, of the order of 103 km2, for several days. Extratropical Cyclone: These are cyclones formed in locations outside the tropical zone. Associated with a frontal system, they possess a strong counter-clockwise wind circulation in the northern hemisphere. The magnitude of precipitation and wind velocities are relatively lower than those of a tropical cyclone. However, the duration of precipitation is usually longer and the areal extent also is larger. Anticyclones These are regions of high pressure, usually of large areal extent. The weather is usually calm at the centre. Anticyclones cause clockwise wind circulations in the northern hemisphere. Winds are of moderate speed, and at the outer edges, cloudy and precipitation conditions exist. Convective Precipitation In this type of precipitation a packet of air which is warmer than the surrounding air due to localised heating rises because of its lesser density. Air from cooler surroundings flows to take up its place thus setting up a convective cell. The warm air continues to rise, undergoes cooling and results in precipitation. Depending upon the moisture, thermal and other conditions light showers to thunderstorms can be expected in convective precipitation. Usually the areal extent of such rains is small, being limited to a diameter of about 10 km. Orographic Precipitation The moist air masses may get lifted-up to higher altitudes due to the presence of mountain barriers and consequently undergo cooling,

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Engineering Hydrology

condensation and precipitation. Such a precipitation is known as Orographic precipitation. Thus in mountain ranges, the windward slopes have heavy precipitation and the leeward slopes light rainfall.

2.4 CHARACTERISTICS OF PRECIPITATION IN INDIA From the point of view of climate the Indian subcontinent can be considered to have two major seasons and two transitional periods as: l South-west monsoon (June–September) l Transition-I, post-monsoon (October–November) l Winter season (December–February) l Transition-II, Summer, (March–May) The chief precipitation characteristics of these seasons are given below.

South-West Monsoon (June–September) The south-west monsoon (popularly known as monsoon) is the principal rainy season of India when over 75% of the annual rainfall is received over a major portion of the country. Excepting the south-eastern part of the peninsula and Jammu and Kashmir, for the rest of the country the south-west monsoon is the principal source of rain with July as the month which has maximum rain. The monsoon originates in the Indian ocean and heralds its appearance in the southern part of Kerala by the end of May. The onset of monsoon is accompanied by high south-westerly winds at speeds of 30–70 kmph and low-pressure regions at the advancing edge. The monsoon winds advance across the country in two branches: (i) the Arabian sea branch, and (ii) the Bay of Bengal branch. The former sets in at the extreme southern part of Kerala and the latter at Assam, almost simultaneously in the first week of June. The Bay branch first covers the north-eastern regions of the country and turns westwards to advance into Bihar and UP. The Arabian sea branch moves northwards over Karnataka, Maharashtra and Gujarat. Both the branches reach Delhi around the same time by about the fourth week of June. A low-pressure region known as monsoon trough is formed between the two branches. The trough extends from the Bay of Bengal to Rajasthan and the precipitation pattern over the country is generally determined by its position. The monsoon winds increase from June to July and begin to weaken in September. The withdrawal of the monsoon, marked by a substantial rainfall activity starts in September in the northern part of the country. The onset and withdrawal of the monsoon at various parts of the country are shown in Fig. 2.2(a) and Fig. 2.2(b). The monsoon is not a period of continuous rainfall. The weather is generally cloudy with frequent spells of rainfall. Heavy rainfall activity in various parts of the country owing to the passage of low pressure regions is common. Depressions formed in the Bay of Bengal at a frequency of 2–3 per month move along the trough causing excessive precipitation of about 100–200 mm per day. Breaks of about a week in which the rainfall activity is the least is another feature of the monsoon. The south-west monsoon rainfall over the country is indicated in Fig. 2.3. As seen from this figure, the heavy rainfall areas are Assam and the north-eastern region with 200–400 cm, west coast and western ghats with 200–300 cm, West Bengal with 120–160 cm, UP, Haryana and the Punjab with 100–120 cm. The long term average monsoon rainfall over the country is estimated as 95.0 cm.

Precipitation

%

(a)

(b)

Fig. 2.2

(a) Normal Dates of Onset of Monsoon, (b) Normal Dates of Withdrawal of Monsoon (Reproduced from Natural Resources of Humid Tropical Asia—Natural Resources Research, XII. © UNESCO, 1974, with permission of UNESCO)

The territorial waters of India extend into the sea to a distance of 200 nautical miles measured from the appropriate baseline Responsibility for the correctness of the internal details on the map rests with the publisher.

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Engineering Hydrology

Fig. 2.3 Southwest Monsoon Rainfall (cm) over India and Neighbourhood (Reproduced with permission from India Meteorological Department)

Based upon Survey of India map with the permission of the Surveyor General of India © Government of India Copyright 1984 The territorial waters of India extend into the sea to a distance of 200 nautical miles measured from the appropriate baseline Responsibility for the correctness of the internal details on the map rests with the publisher.

Post-Monsoon (October–November) As the south-west monsoon retreats, low-pressure areas form in the Bay of Bengal and a north-easterly flow of air that picks up moisture in the Bay of Bengal is formed. This air mass strikes the east coast of the southern peninsula (Tamil Nadu) and causes rainfall. Also, in this period, especially in November, severe tropical cyclones form in the Bay of Bengal and the Arabian sea. The cyclones formed in the Bay of Bengal are about twice as many as in the Arabian sea. These cyclones strike the coastal areas and cause intense rainfall and heavy damage to life and property.

Winter Season (December–February) By about mid-December, disturbances of extra tropical origin travel eastwards across Afghanistan and Pakistan. Known as western disturbances, they cause moderate to

Precipitation

'

heavy rain and snowfall (about 25 cm) in the Himalayas, and, Jammu and Kashmir. Some light rainfall also occurs in the northern plains. Low-pressure areas in the Bay of Bengal formed in these months cause 10–12 cm of rainfall in the southern parts of Tamil Nadu.

Summer (Pre-monsoon) (March-May) There is very little rainfall in India in this season. Convective cells cause some thunderstorms mainly in Kerala, West Bengal and Assam. Some cyclone activity, dominantly on the east coast, also occurs.

Annual Rainfall The annual rainfall over the country is shown in Fig. 2.4. Considerable areal variation exists for the annual rainfall in India with high rainfall of the magnitude of 200 cm in

Fig. 2.4 Annual Rainfall (cm) over India and Neighbourhood (Reproduced from Natural Resources of Humid Tropical Asia—Natural Resources Research, XII. © UNESCO, 1974, with permission of UNESCO) Based upon Survey of India map with the permission of the Surveyor General of India © Government of India Copyright 1984 The territorial waters of India extend into the sea to a distance of 200 nautical miles measured from the appropriate baseline Responsibility for the correctness of the internal details on the map rests with the publisher.

Engineering Hydrology

Assam and north-eastern parts and the western ghats, and scanty rainfall in eastern Rajasthan and parts of Gujarat, Maharashtra and Karnataka. The average annual rainfall for the entire country is estimated as 117 cm. It is well-known that there is considerable variation of annual rainfall in time at a place. The coefficient of variation, 100 ´ standard deviation Cv = mean of the annual rainfall varies between 15 and 70, from place to place with an average value of about 30. Variability is least in regions of high rainfall and largest in regions of scanty rainfall. Gujarat, Haryana, Punjab and Rajasthan have large variability of rainfall. Some of the interesting statistics relating to the variability of the seasonal and annual rainfall of India are as follows: l A few heavy spells of rain contribute nearly 90% of total rainfall. l While the average annual rainfall of the country is 117 cm, average annual rainfall varies from 10 cm in the western desert to 1100 cm in the North East region. l More than 50% rain occurs within 15 days and less than 100 hours in a year. l More than 80% of seasonal rainfall is produced in 10–20% rain events each lasting 1–3 days.

2.5 MEASUREMENT OF PRECIPITATION A. Rainfall Precipitation is expressed in terms of the depth to which rainfall water would stand on an area if all the rain were collected on it. Thus 1 cm of rainfall over a catchment area of l km2 represents a volume of water equal to 104 m3. In the case of snowfall, an equivalent depth of water is used as the depth of precipitation. The precipitation is collected and measured in a raingauge. Terms such as pluviometer, ombrometer and hyetometer are also sometimes used to designate a raingauge. A raingauge essentially consists of a cylindrical-vessel assembly kept in the open to collect rain. The rainfall catch of the raingauge is affected by its exposure conditions. To enable the catch of raingauge to accurately represent the rainfall in the area surrounding the raingauge standard settings are adopted. For siting a raingauge the following considerations are important: l The ground must be level and in the open and the instrument must present a horizontal catch surface. l The gauge must be set as near the ground as possible to reduce wind effects but it must be sufficiently high to prevent splashing, flooding, etc. l The instrument must be surrounded by an open fenced area of at least 5.5 m ´ 5.5 m. No object should be nearer to the instrument than 30 m or twice the height of the obstruction. Raingauges can be broadly classified into two categories as (i) nonrecording raingauges and (ii) recording gauges.

Nonrecording Gauges The nonrecording gauge extensively used in India is the Symons’ gauge. It essentially consists of a circular collecting area of 12.7 cm (5.0 inch) diameter connected to a

Precipitation

funnel. The rim of the collector is set in a horizontal plane at a height of 30.5 cm above the ground level. The funnel discharges the rainfall catch into a receiving vessel. The funnel and receiving vessel are housed in a metallic container. Figure 2.5 shows the details of the installation. Water contained in the receiving vessel is measured by a suitably graduated measuring glass, with an accuracy up to 0.1 mm. Recently, the India Meteorological Department (IMD) has changed over to the use of Fig. 2.5 Nonrecording Raingauge (Symons’ Gauge) fibreglass reinforced polyester raingauges, which is an improvement over the Symons’ gauge. These come in different combinations of collector and bottle. The collector is in two sizes having areas of 200 and 100 cm2 respectively. Indian standard (IS: 5225–1969) gives details of these new raingauges. For uniformity, the rainfall is measured every day at 8.30 AM (IST) and is recorded as the rainfall of that day. The receiving bottle normally does not hold more than 10 cm of rain and as such in the case of heavy rainfall the measurements must be done more frequently and entered. However, the last reading must be taken at 8.30 AM and the sum of the previous readings in the past 24 hours entered as total of that day. Proper care, maintenance and inspection of raingauges, especially during dry weather to keep the instrument free from dust and dirt is very necessary. The details of installation of nonrecording raingauges and measurement of rain are specified in Indian Standard (IS: 4986–1968). This raingauge can also be used to measure snowfall. When snow is expected, the funnel and receiving bottle are removed and the snow is allowed to collect in the outer metal container. The snow is then melted and the depth of resulting water measured. Antifreeze agents are sometimes used to facilitate melting of snow. In areas where considerable snowfall is expected, special snowgauges with shields (for minimizing the wind effect) and storage pipes (to collect snow over longer durations) are used.

Recording Gauges Recording gauges produce a continuous plot of rainfall against time and provide valuable data of intensity and duration of rainfall for hydrological analysis of storms. The following are some of the commonly used recording raingauges. Tipping-Bucket Type This is a 30.5 cm size raingauge adopted for use by the US Weather Bureau. The catch from the funnel falls onto one of a pair of small buckets. These buckets are so balanced that when 0.25 mm of rainfall collects in one bucket, it tips and brings the other one in position. The water from the tipped bucket is col-

Engineering Hydrology

lected in a storage can. The tipping actuates an electrically driven pen to trace a record on clockwork-driven chart. The water collected in the storage can is measured at regular intervals to provide the total rainfall and also serve as a check. It may be noted that the record from the tipping bucket gives data on the intensity of rainfall. Further, the instrument is ideally suited for digitalizing of the output signal. Weighing-Bucket Type In this raingauge the catch from the funnel empties into a bucket mounted on a weighing scale. The weight of the bucket and its contents are recorded on a clock-work-driven chart. The clockwork mechanism has the capacity to run for as long as one week. This instrument gives a plot of the accumulated rainfall against the elapsed time, i.e. the mass curve of rainfall. In some instruments of this type the recording unit is so constructed that the pen reverses its direction at every preset value, say 7.5 cm (3 in.) so that a continuous plot of storm is obtained. Natural-Syphon Type This type of recording raingauge is also known as floattype gauge. Here the rainfall collected by a funnel-shaped collector is led into a float chamber causing a float to rise. As the float rises, a pen attached to the float through a lever system records the elevation of the float on a rotating drum driven by a clockwork mechanism. A syphon arrangement empties the float chamber when the float has reached a pre-set maximum level. This type of raingauge is adopted as the standard recording-type raingauge in India and its details are described in Indian Standard (IS: 5235–1969). A typical chart from this type of raingauge is shown in Fig. 2.6. This chart shows a rainfall of 53.8 mm in 30 h. The vertical lines in the pen-trace correspond to the sudden emptying of the float chamber by syphon action which resets the pen to zero level. It is obvious that the natural syphon-type recording raingauge gives a plot of the mass curve of rainfall.

Fig. 2.6 Recording from a Natural Syphon-type Gauge (Schematic)

Telemetering Raingauges These raingauges are of the recording type and contain electronic units to transmit the data on rainfall to a base station both at regular intervals and on interrogation. The tipping-bucket type raingauge, being ideally suited, is usually adopted for this purpose. Any of the other types of recording raingauges can also be used equally effectively. Telemetering gauges are of utmost use in gathering rainfall data from mountainous and generally inaccessible places.

Precipitation

!

Radar Measurement of Rainfall The meteorological radar is a powerful instrument for measuring the areal extent, location and movement of rain storms. Further, the amounts of rainfall over large areas can be determined through the radar with a good degree of accuracy. The radar emits a regular succession of pulses of electromagnetic radiation in a narrow beam. When raindrops intercept a radar beam, it has been shown that CZ Pr = (2.1) r2 where Pr = average echopower, Z = radar-echo factor, r = distance to target volume and C = a constant. Generally the factor Z is related to the intensity of rainfall as Z = aIb (2.2) where a and b are coefficients and I = intensity of rainfall in mm/h. The values a and b for a given radar station have to be determined by calibration with the help of recording raingauges. A typical equation for Z is Z = 200 I1.60 Meteorological radars operate with wavelengths ranging from 3 to 10 cm, the common values being 5 and 10 cm. For observing details of heavy flood-producing rains, a 10-cm radar is used while for light rain and snow a 5-cm radar is used. The hydrological range of the radar is about 200 km. Thus a radar can be considered to be a remote-sensing super gauge covering an areal extent of as much as 100,000 km2. Radar measurement is continuous in time and space. Present-day developments in the field include (i) On-line processing of radar data on a computer and (ii) Doppler-type radars for measuring the velocity and distribution of raindrops.

B. Snowfall Snowfall as a form of precipitation differs from rainfall in that it may accumulate over a surface for some time before it melts and causes runoff. Further, evaporation from the surface of accumulated snow surface is a factor to be considered in analysis dealing with snow. Water equivalent of snowfall is included in the total precipitation amounts of a station to prepare seasonal and annual precipitation records. Depth of Snowfall Depth of snowfall is an important indicator for many engineering applications and in hydrology it is useful for seasonal precipitation and long-term runoff forecasts. A graduated stick or staff is used to measure the depth of snow at a selected place. Average of several measurements in an area is taken as the depth of snow in a snowfall event. Snow stakes are permanent graduated posts used to measure total depth of accumulated snow at a place. Snow boards are 40 cm side square boards used to collect snow samples. These boards are placed horizontally on a previous accumulation of snow and after a snowfall event the snow samples are cut off from the board and depth of snow and water equivalent of snow are derived and recorded. Water Equivalent of Snow Water equivalent of snow is the depth of water that would result in melting of a unit of snow. This parameter is important in assessing the seasonal water resources of a catchment as well as in estimates of stream flow and floods due to melting of snow.

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Engineering Hydrology

The amount of water present in a known depth of snow could be estimated if the information about the density of snow is available. The density of snow, however, varies quite considerably. Freshly fallen snow may have a density in the range of 0.07 to 0.15 with an average value of about 0.10. The accumulated snow however causes compaction and in regions of high accumulation densities as high as 0.4 to 0.6 is not uncommon. Where specific data is not available, it is usual to assume the density of fresh snow as 0.10. Water equivalent of snow is obtained in two ways: Snow Gauges Like rain gauges, snow gauges are receptacles to catch precipitation as it falls in a specified sampling area. Here, a large cylindrical receiver 203 mm in diameter is used to collect the snow as it falls. The height of the cylinder depends upon the snow storage needed at the spot as a consequence of accessibility etc. and may range from 60 cm to several metres. The receiver is mounted on a tower to keep the rim of the gauge above the anticipated maximum depth of accumulated snow in the area. The top of the cylinder is usually a funnel like fulcrum of cone with side slopes not less than 1 H: 6 V, to minimize deposits of ice on the exterior of the gauge. Also, a windshield is provided at the top. Melting agents or heating systems are sometimes provided in the remote snow gauges to reduce the size of the containers. The snow collected in the cylinder is brought in to a warm room and the snow melted by adding a pre-measured quantity of hot water. Through weighing or by volume measurements, the water equivalent of snow is ascertained and recorded. Snow Tubes Water equivalent of accumulated snow is measured by means of snow tubes which are essentially a set of telescopic metal tubes. While a tube size of 40 mm diameter is in normal use, higher sizes up to 90 mm diameter are also in use. The main tube is provided with a cutter edge for easy penetration as well as to enable extracting of core sample. Additional lengths of tube can be attached to the main tube depending upon the depth of snow. To extract a sample, the tube is driven into the snow deposit till it reaches the bottom of the deposit and then twisted and turned to cut a core. The core is extracted carefully and studied for its physical properties and then melted to obtain water equivalent of the snow core. Obviously, a large number of samples are needed to obtain representative values for a large area deposit. Usually, the sampling is done along an established route with specified locations called snow course.

2.6 RAINGAUGE NETWORK Since the catching area of a raingauge is very small compared to the areal extent of a storm, it is obvious that to get a representative picture of a storm over a catchment the number of raingauges should be as large as possible, i.e. the catchment area per gauge should be small. On the other hand, economic considerations to a large extent and other considerations, such as topography, accessibility, etc. to some extent restrict the number of gauges to be maintained. Hence one aims at an optimum density of gauges from which reasonably accurate information about the storms can be obtained. Towards this the World Meteorological Organisation (WMO) recommends the following densities. l In flat regions of temperate, Mediterranean and tropical zones Ideal—1 station for 600–900 km2 Acceptable—1 station for 900–3000 km2

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In mountainous regions of temperate, Mediterranean and topical zones Ideal—1 station for 100–250 km2 Acceptable—1 station for 25–1000 km2 2 l In arid and polar zones: 1 station for 1500–10,000 km depending on the feasibility. Ten per cent of raingauge stations should be equipped with self-recording gauges to know the intensities of rainfall. From practical considerations of Indian conditions, the Indian Standard (IS: 4987– 1968) recommends the following densities as sufficient. 2 l In plains: 1 station per 520 km ; 2 l In regions of average elevation 1000 m: 1 station per 260–390 km ; and 2 l In predominantly hilly areas with heavy rainfall: 1 station per 130 km . l

Adequacy of Raingauge Stations If there are already some raingauge stations in a catchment, the optimal number of stations that should exist to have an assigned percentage of error in the estimation of mean rainfall is obtained by statistical analysis as 2

æ Cv ö (2.3) N= ç è A ÷ø where N = optimal number of stations, A = allowable degree of error in the estimate of the mean rainfall and Cv = coefficient of variation of the rainfall values at the existing m stations (in per cent). If there are m stations in the catchment each recording rainfall values P1, P2,…, Pi,… Pm in a known time, the coefficient of variation Cv is calculated as: 100 ´ I m - 1 Cv = P

where

ém 2 ù ê å ( Pi - P ) ú 1 ú = standard deviation Im–1 = ê m - 1 ûú ëê Pi = precipitation magnitude in the ith station

1æm ö å Pi = mean precipitation m çè 1 ÷ø In calculating N from Eq. (2.3) it is usual to take A = 10% . It is seen that if the value of A is small, the number of raingauge stations will be more. According to WMO recommendations, at least 10% of the total raingauges should be of self-recording type.

P=

EXAMPLE 2.1 A catchment has six raingauge stations. In a year, the annual rainfall recorded by the gauges are as follows: Station Rainfall (cm)

A 82.6

B 102.9

C 180.3

D 110.3

E 98.8

F 136.7

For a 10% error in the estimation of the mean rainfall, calculate the optimum number of stations in the catchment.

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Engineering Hydrology

SOLUTION: For this data, m=6 Im–1 = 35.04 P = 118.6 100 ´ 35.04 Cv = = 29.54 118.6

A = 10

2

29.54 ö N = æç = 8.7, say 9 stations è 10 ÷ø The optimal number of stations for the catchment is 9. Hence three more additional stations are needed.

2.7 PREPARATION OF DATA Before using the rainfall records of a station, it is necessary to first check the data for continuity and consistency. The continuity of a record may be broken with missing data due to many reasons such as damage or fault in a raingauge during a period. The missing data can be estimated by using the data of the neighbouring stations. In these calculations the normal rainfall is used as a standard of comparison. The normal rainfall is the average value of rainfall at a particular date, month or year over a specified 30-year period. The 30-year normals are recomputed every decade. Thus the term normal annual percipitation at station A means the average annual precipitation at A based on a specified 30-years of record.

Estimation of Missing Data Given the annual precipitation values, P1 P2, P3, … Pm at neighbouring M stations 1,2, 3, …, M respectively, it is required to find the missing annual precipitation Px at a station X not included in the above M stations. Further, the normal annual precipitations N1 N2, …, Ni … at each of the above (M + 1) stations including station X are known. If the normal annual precipitations at various stations are within about 10% of the normal annual precipitation at station X, then a simple arithmetic average procedure is followed to estimate Px. Thus 1 Px = [P1 + P2 + … + Pm] (2.4) M If the normal precipitations vary considerably, then Px is estimated by weighing the precipitation at the various stations by the ratios of normal annual precipitations. This method, known as the normal ratio method, gives Px as N x é P1 Pm ù P2 + +¼+ Px = (2.5) ê ú M ë N1 N 2 Nm û EXAMPLE 2.2 The normal annual rainfall at stations A, B, C, and D in a basin are 80.97, 67.59, 76.28 and 92.01 cm respectively. In the year 1975, the station D was inoperative and the stations A, B and C recorded annual precipitations of 91.11, 72.23 and 79.89 cm respectively. Estimate the rainfall at station D in that year. SOLUTION: As the normal rainfall values vary more than 10%, the normal ratio method is adopted. Using Eq. (2.5), PD =

92.01 æ 91.11 72.23 79.89 ö = 99.48 cm ´ç + + è 80.79 67.59 76.28 ÷ø 3

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Test for Consistency of Record If the conditions relevant to the recording of a raingauge station have undergone a significant change during the period of record, inconsistency would arise in the rainfall data of that station. This inconsistency would be felt from the time the significant change took place. Some of the common causes for inconsistency of record are: (i) shifting of a raingauge station to a new location, (ii) the neighbourhood of the station undergoing a marked change, (iii) change in the ecosystem due to calamities, such as forest fires, land slides, and (iv) occurrence of observational error from a certain date. The checking for inconsistency of a record is done by the double-mass curve technique. This technique is based on the principle that when each recorded data comes from the same parent population, they are consistent. A group of 5 to 10 base stations in the neighbourhood of the problem station X is selected. The data of the annual (or monthly or seasonal mean) rainfall of the station X and also the average rainfall of the group of base stations covering a long period is arranged in the reverse chronological order (i.e. the latest record as the first entry and the oldest record as the last entry in the list). The accumulated precipitation of the station X (i.e. SPx) and the accumulated values of the average of the group of base stations (i.e. SPav) are calculated starting from the latest record. Values of SPx are plotted against SPav for various consecutive time periods (Fig. 2.7). A decided break in the slope of the resulting plot indicates a change in the precipitation regime of station X. The precipitation values at station X beyond the period of change of regime (point 63 in Fig. 2.7) is corrected by using the relation Pcx = Px where

Me Ma

Pcx = corrected precipitation at any time period t1 at station X Px = original recorded precipitation at time period t1 at station X

Fig. 2.7 Double-mass Curve

(2.6)

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Engineering Hydrology

Mc = corrected slope of the double-mass curve Ma = original slope of the double-mass curve In this way the older records are brought to the new regime of the station. It is apparent that the more homogeneous the base station records are, the more accurate will be the corrected values at station X. A change in the slope is normally taken as significant only where it persists for more than five years. The double-mass curve is also helpful in checking systematic arithmetical errors in transferring rainfall data from one record to another. EXAMPLE 2.3 Annual rainfall data for station M as well as the average annual rainfall values for a group of ten neighbouring stations located in a meteorologically homogeneous region are given below.

Year

1950 1951 1952 1953 1954 1955 1956 1957 1958 1959 1960 1961 1962 1963 1964

Annual Rainfall of Station M (mm)

Average Annual Rainfall of the group (mm)

Year

676 578 95 462 472 699 479 431 493 503 415 531 504 828 679

780 660 110 520 540 800 540 490 560 575 480 600 580 950 770

1965 1966 1967 1968 1969 1970 1971 1972 1973 1974 1975 1976 1977 1978 1979

Annual Rainfall of Station M (mm)

Average Annual Rainfall of the group (mm)

1244 999 573 596 375 635 497 386 438 568 356 685 825 426 612

1400 1140 650 646 350 590 490 400 390 570 377 653 787 410 588

Test the consistency of the annual rainfall data of station M and correct the record if there is any discrepancy. Estimate the mean annual precipitation at station M.

SOLUTION: The data is sorted in descending order of the year, starting from the latest year 1979. Cumulative values of station M rainfall (SPm) and the ten station average rainfall values (SPav) are calculated as shown in Table 2.1. The data is then plotted with SPm on the Y-axis and SPav on the X-axis to obtain a double mass curve plot (Fig. 2.8). The value of the year corresponding to the plotted points is also noted on the plot. It is seen that the data plots as two straight lines with a break of grade at the year 1969. This represents a change in the regime of the station M after the year 1968. The slope of the best straight line for the period 1979–1969 is Mc = 1.0295 and the slope of the best straight line for the period 1968–1950 is Ma = 0.8779. The correction ratio to bring the old records (1950–1968) to the current (post 1968) regime is = Mc/Ma = 1.0295/0.8779 = 1.173. Each of the pre 1969 annual rainfall value is

Fig. 2.8 Double Mass Curve of Annual Rainfall at Station M

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multiplied by the correction ratio of 1.173 to get the adjusted value. The adjusted values at station M are shown in Col. 5 of Table . The finalized values of Pm (rounded off to nearest mm) for all the 30 years of record are shown in Col. 7. The mean annual precipitation at station M (based on the corrected time series) = (19004/30) = 633.5 mm

Table 2.1 Calculation of Double Mass Curve of Example 2.3 1 Year

2 Pm (mm)

3 SPm (mm)

4 Pav (mm)

5 Pav (mm)

1979 1978 1977 1976 1975 1974 1973 1972 1971 1970 1969 1968 1967 1966 1965 1964 1963 1962 1961 1960 1959 1958 1957 1956 1955 1954 1953 1952 1951 1950

612 426 825 685 356 568 438 386 497 635 375 596 573 999 1244 679 828 504 531 415 503 493 431 479 699 472 462 95 578 676

612 1038 1863 2548 2904 3472 3910 4296 4793 5428 5803 6399 6972 7971 9215 9894 10722 11226 11757 12172 12675 13168 13599 14078 14777 15249 15711 15806 16384 17060

588 410 787 653 377 570 390 400 490 590 350 646 650 1140 1400 770 950 5801 600 480 575 560 490 540 800 540 520 110 660 780

588 998 1785 2438 2815 3385 3775 4175 4665 5255 5605 6251 6901 8041 9441 10211 11161 11741 12341 12821 13396 13956 14446 14986 15786 16326 16846 16956 17616 18396

6 Adjusted values of Pm (mm)

7 Finalised values of Pm (mm)

698.92 671.95 1171.51 1458.82 796.25 970.98 591.03 622.70 486.66 589.86 578.13 505.43 561.72 819.71 553.51 541.78 111.41 677.81 792.73

612 426 825 685 356 568 438 386 497 635 375 699 672 1172 1459 796 971 591 623 487 590 578 505 562 820 554 542 111 678 193

Total of Pm = 19004 mm Mean of Pm = 633.5 mm

2.8 PRESENTATION OF RAINFALL DATA A few commonly used methods of presentation of rainfall data which have been found to be useful in interpretation and analysis of such data are given as follows:

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Mass Curve of Rainfall The mass curve of rainfall is a plot of the accumulated precipitation against time, plotted in chronological order. Records of float type and weighing bucket type gauges are of this form. A typical mass curve of rainfall at a station during a storm is shown in Fig. 2.9. Mass curves of rainfall are very useful in extracting the information on the duration and magnitude of a storm. Also, intensities at various time intervals in a storm can be obtained by the slope of the curve. For nonrecording raingauges, mass curves are prepared from a knowledge of the approximate beginning and end of a storm and by using the mass curves of adjacent recording gauge stations as a guide.

Fig. 2.9 Mass Curve of Rainfall

Hyetograph A hyetograph is a plot of the intensity of rainfall against the time interval. The hyetograph is derived from the mass curve and is usually represented as a bar chart (Fig. 2.10). It is a very convenient way of representing the characteristics of a storm and is particularly important Fig. 2.10 Hyetograph of a Storm in the development of design storms to predict extreme floods. The area under a hyetograph represents the total precipitation received in the period. The time interval used depends on the purpose, in urban-drainage problems small durations are used while in flood-flow computations in larger catchments the intervals are of about 6 h.

Point Rainfall Point rainfall, also known as station rainfall refers to the rainfall data of a station. Depending upon the need, data can be listed as daily, weekly, monthly, seasonal or annual values for various periods. Graphically these data are represented as plots of

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magnitude vs chronological time in the form of a bar diagram. Such a plot, however, is not convenient for discerning a trend in the rainfall as there will be considerable variations in the rainfall values leading to rapid changes in the plot. The trend is often discerned by the method of moving averages, also known as moving means. Moving average Moving average is a technique for smoothening out the high frequency fluctuations of a time series and to enable the trend, if any, to be noticed. The basic principle is that a window of time range m years is selected. Starting from the first set of m years of data, the average of the data for m years is calculated and placed in the middle year of the range m. The window is next moved sequentially one time unit (year) at a time and the mean of the m terms in the window is determined at each window location. The value of m can be 3 or more years; usually an odd value. Generally, the larger the size of the range m, the greater is the smoothening. There are many ways of averaging (and consequently the plotting position of the mean) and the method described above is called Central Simple Moving Average. Example 2.4 describes the application of the method of moving averages. EXAMPLE 2.4 Annual rainfall values recorded at station M for the period 1950 to 1979 is given in Example 2.3. Represent this data as a bar diagram with time in chronological order. (i) Identify those years in which the annual rainfall is (a) less than 20% of the mean, and (b) more than the mean. (ii) Plot the three-year moving mean of the annual rainfall time series. SOLUTION: (i) Figure 2.11 shows the bar chart with height of the column representing the annual rainfall depth and the position of the column representing the year of occurrence. The time is arranged in chronological order. The mean of the annual rainfall time series is 568.7 mm. As such, 20% less than the mean = 426.5 mm. Lines representing these values are shown in Fig. 2.11 as horizontal lines. It can be seen that in 6 years, viz. 1952, 1960, 1969, 1972, 1975 and 1978, the

Fig. 2.11 Bar Chart of Annual Rainfall at Station M

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annual rainfall values are less than 426.5 mm. In thirteen years, viz. 1950, 1951, 1955, 1963, 1964, 1965, 1966, 1967, 1968, 1970, 1976, 1977 and 1978, the annual rainfall was more than the mean. (ii) Moving mean calculations are shown in Table 2.2. Three-year moving mean curve is shown plotted in Fig. 2.12 with the moving mean value as the ordinate and the time in chronological order as abscissa. Note that the curve starts from 1951 and ends in the year 1978. No apparent trend is indicated in this plot.

Table 2.2 Computation of Three-year Moving Mean 1

2

3

4

Year

Annual Rainfall (mm) Pi

Three consecutive year total for moving mean (Pi–1 + Pi + Pi + 1)

3-year moving mean (Col. 3/3)*

676 + 578 + 95 = 1349 578 + 95 + 462 = 1135 95 + 462 + 472 = 1029 462 + 472 + 699 = 1633 472 + 699 + 479 = 1650 699 + 479 + 431 = 1609 479 + 431 + 493 = 1403 431 + 493 + 503 = 1427 493 + 503 + 415 = 1411 503 + 415 + 531 = 1449 415 + 531 + 504 = 1450 531 + 504 + 828 = 1863 504 + 828 + 679 = 2011 828 + 679 + 1244 = 2751 679 + 1244 + 999 = 2922 1244 + 999 + 573 = 2816 999 + 573 + 596 = 2168 573 + 596 + 375 = 1544 596 + 375 + 635 = 1606 375 + 635 + 497 = 1507 635 + 497 + 386 = 1518 497 + 386 + 438 = 1321 386 + 438 + 568 = 1392 438 + 568 + 356 = 1362 568 + 356 + 685 = 1609 356 + 685 + 825 = 1866 685 + 825 + 426 = 1936 825 + 426 + 162 = 1863

449.7 378.3 343.0 544.3 550.0 536.3 467.7 475.7 470.3 483.0 483.3 621.0 670.3 917.0 974.0 938.7 722.7 514.7 535.3 502.3 506.0 440.3 464.0 454.0 536.3 622.0 645.3 621.0

1950 1951 1952 1953 1954 1955 1956 1957 1958 1959 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 1970 1971 1972 1973 1974 1975 1976 1977 1978 1979

676 578 95 462 472 699 479 431 493 503 415 531 504 828 679 1244 999 573 596 375 635 497 386 438 568 356 685 825 426 612

*The moving mean is recorded at the mid span of 3 years.

2.9 MEAN PRECIPITATION OVER AN AREA As indicated earlier, raingauges represent only point sampling of the areal

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Engineering Hydrology

Fig. 2.12 Three-year Moving Mean distribution of a storm. In practice, however, hydrological analysis requires a knowledge of the rainfall over an area, such as over a catchment. To convert the point rainfall values at various stations into an average value over a catchment the following three methods are in use: (i) Arithmetical-mean method, (ii) Thiessen-polygon method, and (iii) Isohyetal method.

Arithmetical-Mean Method When the rainfall measured at various stations in a catchment show little variation, the average precipitation over the catchment area is taken as the arithmetic mean of the station values. Thus if P1, P2,…, Pi, …Pn are the rainfall values in a given period in N stations within a catchment, then the value of the mean precipitation P over the catchment by the arithmetic-mean method is P + P2 + ¼ + Pi + ¼ + Pn 1 N (2.7) P= 1 = åP N N i =1 i In practice, this method is used very rarely.

Thiessen-Mean Method In this method the rainfall recorded at each station is given a weightage on the basis of an area closest to the station. The procedure of determining the weighing area is as follows: Consider a catchment area as in Fig. 2.13 containing three raingauge stations. There are three stations outside the catchment but in its neighbourhood. The catchment area is drawn to scale and the positions of the six stations marked on it. Stations 1 to 6 are joined to form a network of triangles. Perpendicular bisectors for each of the sides of the triangle are drawn. These bisectors form a polygon around each station. The boundary of the catchment, if it cuts the bisectors is taken as the outer limit of the polygon. Thus for station 1, the bounding polygon is abcd. For station 2, kade is taken as the bounding polygon. These bounding polygons are called Thiessen polygons. The areas of these six Thiessen polygons are determined either with a planimeter or

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A = total catchment area Station Bounded by 1 abcd 2 kade 3 edcgf 4 fgh 5 hgcbj 6 jbak

Area

Weightage

A1 A2 A3 A4 A5 A6

A1/A A2/A A3/A A4/A A5/A A6/A

Fig. 2.13 Thiessen Polygons by using an overlay grid. If P1 P2,… , P6 are the rainfall magnitudes recorded by the stations 1, 2,…, 6 respectively, and A1, A2,…, A6 are the respective areas of the Thiessen polygons, then the average rainfall over the catchment P is given by P1 A1 + P2 A2 + ¼ + P6 A6 P= ( A1 + A2 + ¼ + A6 ) Thus in general for M stations, M

å Pi Ai

P=

i =1

A

M

Ai

i =1

A

= å Pi

(2.8)

Ai The ratio is called the weightage factor for each station. A The Thiessen-polygon method of calculating the average percipitation over an area is superior to the arithmetic-average method as some weightage is given to the various stations on a rational basis. Further, the raingauge stations outside the catchment are also used effectively. Once the weightage factors are determined, the calculation of P is relatively easy for a fixed network of stations.

Isohyetal Method An isohyet is a line joining points of equal rainfall magnitude. In the isohyetal method, the catchment area is drawn to scale and the raingauge stations are marked. The recorded values for which areal average P is to be determined are then marked on the plot at appropriate stations. Neighbouring stations outside the catchment are also considered. The isohyets of various values are then drawn by considering point rain-

Fig. 2.14 Isohyetals of a Storm

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falls as guides and interpolating between them by the eye (Fig. 2.14). The procedure is similar to the drawing of elevation contours based on spot levels. The area between two adjacent isohyets are then determined with a planimeter. If the isohyets go out of catchment, the catchment boundary is used as the bounding line. The average value of the rainfall indicated by two isohyets is assumed to be acting over the inter-isohyet area. Thus P1, P2, …, Pn are the values of isohyets and if a1, a2, …, an-1 are the inter-isohyet areas respectively, then the mean precipitation over the catchment of area A is given by æ Pn - 1 + Pn ö æ P2 + P3 ö æ P + P2 ö + a2 ç + ¼ + an - 1 ç a1 ç 1 ÷ø è 2 ÷ø è 2 ÷ø è 2 P= (2.9) A The isohyet method is superior to the other two methods especially when the stations are large in number.

EXAMPLE 2.5 In a catchment area, approximated by a circle of diameter 100 km, four rainfall stations are situated inside the catchment and one station is outside in its neighbourhood. The coordinates of the centre of the catchment and of the five stations are given below. Also given are the annual precipitation recorded by the five stations in 1980. Determine the average annual precipitation by the Thiessen-mean method. Centre: (100, 100) Distance are in km Station Coordinates Precipitation (cm)

1 (30, 80) 85.0

Diameter: 100 km.

2 (70, 100) 135.2

SOLUTION: The catchment area is drawn to scale and the stations are marked on it (Fig. 2.15). The stations are joined to form a set of triangles and the perpendicular bisector of each side is then drawn. The Thiessen-polygon area enclosing each station is then identified. It may be noted that station 1 in this problem does not have any area of influence in the catchment. The areas of various Thiessen polygons are determined either by a planimeter or by placing an overlay grid. Station

1 2 3 4 5 Total

3 (100, 140) 95.3

4 (130, 100) 146.4

Fig. 2.15 Thiessen Polygons— Example 2.5

Boundary of area

Area (km2)

Fraction of total area

Rainfall

— abcd dce ecbf fba

— 2141 1609 2141 1963

— 0.2726 0.2049 0.2726 0.2499

85.0 135.2 95.3 146.4 102.2

7854

1.000

Mean precipitation = 121.84 cm.

5 (100, 70) 102.2

Weighted P (cm) (col. 4 ´ col. 5) — 36.86 19.53 39.91 25.54 121. 84

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EXAMPLE 2.6 The isohyets due to a storm in a catchment were drawn (Fig. 2.14) and the area of the catchment bounded by isohyets were tabulated as below. Isohyets (cm)

Area (km2)

Station–12.0 12.0–10.0 10.0–8.0 8.0–6.0 6.0–4.0

30 140 80 180 20

Estimate the mean precipitation due to the storm.

SOLUTION: For the first area consisting of a station surrounded by a closed isohyet, a precipitation value of 12.0 cm is taken. For all other areas, the mean of two bounding isohyets are taken. Isohytes

Average value of P (cm)

1

Area (km2)

2

12.0 12.0–10.0 10.0–8.0 8.0–6.0 6.0–4.0 Total

12.0 11.0 9.0 7.0 5.0

3

Fraction of total area (col. 3/450)

Weighted P (cm) (col. 2 ´ col. 4)

4

30 140 80 180 20 450

5

0.0667 0.3111 0.1778 0.4000 0.0444 1.0000

0.800 3.422 1.600 2.800 0.222 8.844

Mean precipitation P = 8.84 cm

2.10 DEPTH-AREA-DURATION RELATIONSHIPS The areal distribution characteristics of a storm of given duration is reflected in its depth-area relationship. A few aspects of the interdependency of depth, area and duration of storms are discussed below.

Depth-Area Relation For a rainfall of a given duration, the average depth decreases with the area in an exponential fashion given by P = P0 exp (–KAn) (2.10) where P = average depth in cm over an area A km2, P0 = highest amount of rainfall in cm at the storm centre and K and n are constants for a given region. On the basis of 42 severemost storms in north India, Dhar and Bhattacharya3 (1975) have obtained the following values for K and n for storms of different duration: Duration

K

n

1 day 2 days 3 days

0.0008526 0.0009877 0.001745

0.6614 0.6306 0.5961

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Engineering Hydrology

Since it is very unlikely that the storm centre coincides over a raingauge station, the exact determination of P0 is not possible. Hence in the analysis of large area storms the highest station rainfall is taken as the average depth over an area of 25 km2. Equation (2.10) is useful in extrapolating an existing storm data over an area. Maximum Depth-Area-Duration Curves In many hydrological studies involving estimation of severe floods, it is necessary to have information on the maximum amount of rainfall of various durations occurring over various sizes of areas. The development of relationship, between maximum deptharea-duration for a region is known as DAD analysis and forms an important aspect of hydro-meteorological study. References 2 and 9 can be consulted for details on DAD analysis. A brief description of the analysis is given below. First, the severemost rainstorms that have occurred in the region under question are considered. Isohyetal maps and mass curves of the storm are compiled. A depth-area curve of a given duration of the storm is prepared. Then from a study of the mass curve of rainfall, various durations and the maximum depth of rainfall in these durations are noted. The maximum depth-area curve for a given duration D is prepared by assuming the area distribution of rainfall for smaller duration to be similar to the total storm. The procedure is then repeated for different storms and the envelope curve of maximum depth-area for duration D is obtained. A similar procedure for various values of D results in a family of envelope curves of maximum depth vs area, with duration as the third parameter (Fig. 2.16). These curves are called DAD curves. Figure 2.16 shows typical DAD curves for a catchment. In this the average depth denotes the depth averaged over the area under consideration. It may be seen that the maximum depth for a given storm decreases with the area; for a given area the maximum depth increases with the duration.

Fig. 2.16 Typical DAD Curves Preparation of DAD curves involves considerable computational effort and requires meteorological and topographical information of the region. Detailed data on severemost storms in the past are needed. DAD curves are essential to develop design

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storms for use in computing the design flood in the hydrological design of major structures such as dams. Table 2.3 Maximum (Observed) Rain Depths (cm) over Plains of North India4, 5 Area in km2 ´ 104 Duration 1 day 2 days 3 days

.026

0.13

0.26

81.0* 76.5* 71.1 102.9* 97.5* 93.2* 121.9† 110.7† 103.l†

1.3 47.2* 73.4* 79.2†

2.6

5.2

37.1 * 26.4 58.7* 42.4* 67.1† 54.6†

7.8 20.3† 35.6† 48.3†

10.5

13.0

18.0† 16.0† 31.5† 27.9† 42.7† 38.9†

Note: *—Storm of 17–18 September 1880 over north-west U.P. †—Storm of 28–30 July 1927 over north Gujarat.

Maximum rain depths observed over the plains of north India are indicated in Table 2.3. These were due to two storms, which are perhaps the few severe most recorded rainstorms over the world.

2.11 FREQUENCY OF POINT RAINFALL In many hydraulic-engineering applications such as those concerned with floods, the probability of occurrence of a particular extreme rainfall, e.g. a 24-h maximum rainfall, will be of importance. Such information is obtained by the frequency analysis of the point-rainfall data. The rainfall at a place is a random hydrologic process and a sequence of rainfall data at a place when arranged in chronological order constitute a time series. One of the commonly used data series is the annual series composed of annual values such as annual rainfall. If the extreme values of a specified event occurring in each year is listed, it also constitutes an annual series. Thus for example, one may list the maximum 24-h rainfall occurring in a year at a station to prepare an annual series of 24-h maximum rainfall values. The probability of occurrence of an event in this series is studied by frequency analysis of this annual data series. A brief description of the terminology and a simple method of predicting the frequency of an event is described in this section and for details the reader is referred to standard works on probability and statistical methods. The analysis of annual series, even though described with rainfall as a reference is equally applicable to any other random hydrological process, e.g. stream flow. First, it is necessary to correctly understand the terminology used in frequency analysis. The probability of occurrence of an event of a random variable (e.g. rainfall) whose magnitude is equal to or in excess of a specified magnitude X is denoted by P. The recurrence interval (also known as return period) is defined as T = 1/P (2.11) This represents the average interval between the occurrence of a rainfall of magnitude equal to or greater than X. Thus if it is stated that the return period of rainfall of 20 cm in 24 h is 10 years at a certain station A, it implies that on an average rainfall magnitudes equal to or greater than 20 cm in 24 h occur once in 10 years, i.e. in a long period of say 100 years, 10 such events can be expected. However, it does not mean that every 10 years one such event is likely, i.e. periodicity is not implied. The probability of a rainfall of 20 cm in 24 h occurring in anyone year at station A is 1/ T = 1/10 = 0.l.

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Engineering Hydrology

If the probability of an event occurring is P, the probability of the event not occurring in a given year is q = (1– P). The binomial distribution can be used to find the probability of occurrence of the event r times in n successive years. Thus n! Pr, n = nCr Pr q n – r = P r qn - r (2.12) ( n - r )! r ! where Pr, n = probability of a random hydrologic event (rainfall) of given magnitude and exceedence probability P occurring r times in n successive years. Thus, for example, (a) The probability of an event of exceedence probability P occurring 2 times in n successive years is n! P2, n = P2 qn–2 ( n - 2)! 2! (b) The probability of the event not occurring at all in n successive years is P0, n = qn = (1 – P)n (c) The probability of the event occurring at least once in n successive years (2.13) P1 = 1 – qn = 1 – (1 – P)n EXAMPLE 2.7 Analysis of data on maximum one-day rainfall depth at Madras indicated that a depth of 280 mm had a return period of 50 years. Determine the probability of a one-day rainfall depth equal to or greater than 280 mm at Madras occurring (a) once in 20 successive years, (b) two times in 15 successive years, and (c) at least once in 20 successive years. SOLUTION: Here P =

By using Eq. (2.12): (a) n = 20, r = 1

P1, 20 = (b) n = 15, r = 2 P2,15 = (c) By Eq. (2.13)

1 = 0.02 50

20! ´ 0.02 ´ (0.98)19 = 20 ´ 0.02 ´ 0.68123 = 0.272 19!1! 15! 14 ´ (0.02)2 ´ (0.98)13 = 15 ´ ´ 0.0004 ´ 0.769 = 0.323 2 13!2!

P1 = 1 – (l – 0.02)20 = 0.332

Plotting Position The purpose of the frequency analysis of an annual series is to obtain a relation between the magnitude of the event and its probability of exceedence. The probability analysis may be made either by empirical or by analytical methods. A simple empirical technique is to arrange the given annual extreme series in descending order of magnitude and to assign an order number m. Thus for the first entry m = 1, for the second entry m = 2, and so on, till the last event for which m = N = Number of years of record. The probability P of an event equalled to or exceeded is given by the Weibull formula m ö (2.14) P = æç N è + 1 ÷ø The recurrence interval T = 1/P = (N + 1)/m.

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Equation (2.14) is an empirical forTable 2.4 Plotting Position Formulae mula and there are several other such Method P empirical formulae available to calculate P (Table 2.4). The exceedence California m/N probability of the event obtained by the Hazen (m – 0.5)/N use of an empirical formula, such as Weibull m/(N + 1) Eq. (2.14) is called plotting position. Chegodayev (m – 0.3)/(N + 0.4) Blom (m – 0.44)/(N + 0.12) Equation (2.14) is the most popular Gringorten (m – 3/8)/(N + 1/4) plotting position formula and hence only this formula is used in further sections of this book. Having calculated P (and hence T ) for all the events in the series, the variation of the rainfall magnitude is plotted against the corresponding T on a semi-log paper (Fig. 2.17) or log-log paper. By suitable extrapolation of this plot, the rainfall magnitude of specific duration for any recurrence interval can be estimated.

Fig. 2.17 Return Periods of Annual Rainfall at Station A This simple empirical procedure can give good results for small extrapolations and the errors increase with the amount of extrapolation. For accurate work, various analytical calculation procedures using frequency factors are available. Gumbel’s extreme value distribution and Log Pearson Type III method are two commonly used analytical methods and are described in Chap. 7 of this book. If P is the probability of exceedence of a variable having a magnitude M, a common practice is to designate the magnitude M as having (100 P) percent dependability. For example, 75% dependable annual rainfall at a station means the value of annual rainfall at the station that can be expected to be equalled to or exceeded 75% times, (i.e., on an average 30 times out of 40 years). Thus 75% dependable annual rainfall means the value of rainfall in the annual rainfall time series that has P = 0.75, i.e., T =1/P = 1.333 years.

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Engineering Hydrology

EXAMPLE 2.8 The record of annual rainfall at Station A covering a period of 22 years is given below. (a) Estimate the annual rainfall with return periods of 10 years and 50 years. (b) What would be the probability of an annual rainfall of magnitude equal to or exceeding 100 cm occurring at Station A? (b) What is the 75% dependable annual rainfall at station A? Year

Annual rainfall (cm)

1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 1970

130.0 84.0 76.0 89.0 112.0 96.0 80.0 125.0 143.0 89.0 78.0

Year

Annual rainfall (cm)

1971 1972 1973 1974 1975 1976 1977 1978 1979 1980 1981

90.0 102.0 108.0 60.0 75.0 120.0 160.0 85.0 106.0 83.0 95.0

SOLUTION: The data are arranged in descending order and the rank number assigned to the recorded events. The probability P of the event being equalled to or exceeded is calculated by using Weibull formula (Eq. 2.14). Calculations are shown in Table 2.5. It may be noted that when two or more events have the same magnitude (as for m = 13 and 14 in Table 2.5) the probability P is calculated for the largest m value of the set. The return period T is calculated as T = 1 /P. Table 2.5 Calculation of Return Periods N = 22 years m

1 2 3 4 5 6 7 8 9 10 11

Annual Rainfall Probability = m/(N + 1) (cm) 160.0 143.0 130.0 125.0 120.0 112.0 108.0 106.0 102.0 96.0 95.0

0.043 0.087 0.130 0.174 0.217 0.261 0.304 0.348 0.391 0.435 0.478

Return Period T = 1/P (years) 23.000 11.500 7.667 5.750 4.600 3.833 3.286 2.875 2.556 2.300 2.091

m

Annual Rainfall (cm)

12 13 14 15 16 17 18 19 20 21 22

90.0 89.0 89.0 85.0 84.0 83.0 80.0 78.0 76.0 75.0 60.0

Return Probability Period P = m/(N + 1) T = 1/P (Years) 0.522 0.565 0.609 0.652 0.696 0.739 0.783 0.826 0.870 0.913 0.957

1.917 1.643 1.533 1.438 1.353 1.278 1.211 1.150 1.095 1.045

A graph is plotted between the annual rainfall magnitude as the ordinate (on arithmetic scale) and the return period T as the abscissa (on logarithmic scale), (Fig. 2.17). It can be

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seen that excepting the point with the lowest T, a straight line could represent the trend of the rest of data. (a) (i) For T = 10 years, the corresponding rainfall magnitude is obtained by interpolation between two appropriate successive values in Table 2.5, viz. those having T = 11.5 and 7.667 years respectively, as 137.9 cm (ii) for T = 50 years the corresponding rainfall magnitude, by extrapolation of the best fit straight line, is 180.0 cm (b) Return period of an annual rainfall of magnitude equal to or exceeding 100 cm, by 1 interpolation, is 2.4 years. As such the exceedence probability P = = 0.417 2.4 (c) 75% dependable annual rainfall at Station A = Annual rainfall with probability P = 0.75, i.e. T = 1/0.75 = 1.33 years. By interpolation between two successive values in Table 2.7 having T = 1.28 and 1.35 respectively, the 75% dependable annual rainfall at Station A is 82.3 cm.

2.12

MAXIMUM INTENSITY-DURATION-FREQUENCY RELATIONSHIP

Maximum Intensity-Duration Relationship In any storm, the actual intensity as reflected by the slope of the mass curve of rainfall varies over a wide range during the course of the rainfall. If the mass curve is considered divided into N segments of time interval Dt such that the total duration of the storm D = N Dt, then the intensity of the storm for various sub-durations tj = (1. Dt), (2. Dt), (3. Dt),…( j. Dt)… and (N. Dt) could be calculated. It will be found that for each duration (say tj), the intensity will have a maximum value and this could be analysed to obtain a relationship for the variation of the maximum intensity with duration for the storm. This process is basic to the development of maximum intensity duration frequency relationship for the station discussed later on. Briefly, the procedure for analysis of a mass curve of rainfall for developing maximum intensity-duration relationship of the storm is as follows. l Select a convenient time step Dt such that duration of the storm D = N. Dt. l For each duration (say tj = j.,t) the mass curve of rainfall is considered to be divided into consecutive segments of duration tj . For each segment the incremental rainfall dj in duration tj is noted and intensity Ij = dj /tj obtained. l Maximum value of the intensity (Imj) for the chosen tj is noted. l The procedure is repeated for all values of j = 1 to N to obtain a data set of Imj as a function of duration tj. Plot the maximum intensity Im as function of duration t. l It is common to express the variation of Im with t as c Im = ( t + a )b where a, b and c are coefficients obtained through regression analysis. Example 2.9 describes the procedure in detail.

Maximum Depth-Duration Relationship Instead of the maximum intensity Im in a duration t, the product (Im. t) = dm = maximum depth of precipitation in the duration t could be used to relate it to the duration.

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Engineering Hydrology

Such a relationship is known as the maximum depth-duration relationship of the storm. The procedure of developing this relationship is essentially same as that for maximum intensity-duration relationship described earlier. Example 2.9 describes the procedure in detail

Maximum Intensity-Duration-Frequency Relationship If the rainfall data from a self-recording raingauge is available for a long period, the frequency of occurrence of maximum intensity occurring over a specified duration can be determined. A knowledge of maximum intensity of rainfall of specified return period and of duration equal to the critical time of concentration is of considerable practical importance in evaluating peak flows related to hydraulic structures. Briefly, the procedure to calculate the intensity-duration-frequency relationship for a given station is as follows. l M numbers of significant and heavy storms in a particular year Y1 are selected for analysis. Each of these storms are analysed for maximum intensity duration relationship as described in Sec. 2.12.1 l This gives the set of maximum intensity Im as a function of duration for the year Yl. l The procedure is repeated for all the N years of record to obtain the maximum intensity Im (Dj) k for all j = 1 to M and k = 1 to N. l Each record of Im (Dj)k for k = 1 to N constitutes a time series which can be analysed to obtain frequencies of occurrence of various Im (Dj) values. Thus there will be M time series generated. l The results are plotted as maximum intensity vs return period with the Duration as the third parameter (Fig. 2.18). Alternatively, maximum intensity vs duration with frequency as the third variable can also be adopted (Fig. 2.19).

Fig. 2.18 Maximum Intensity-Return Period-Duration Curves Analytically, these relationships are commonly expressed in a condensed form by general form

KT x (2.15) ( D + a )n where i = maximum intensity (cm/h), T = return period (years), D = duration (hours) K, x, a and n are coefficients for the area represented by the station. i=

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Fig. 2.19 Maximum Intensity-Duration-Frequency Curves Sometimes, instead of maximum intensity, maximum depth is used as a parameter and the results are represented as a plot of maximum depth vs duration with return period as the third variable (Fig. 2.20). [Note: While maximum intensity is expressed as a function of duration and return period, it is customary to refer this function Fig. 2.20 Maximum Depth-Durationas intensity-duration-frequency Frequency Curves relationship. Similarly, in the depth-duration-frequency relationship deals with maximum depth in a given duration.] Rambabu et al. (1979)10 have analysed the self-recording rain gauge rainfall records of 42 stations in the country and have obtained the values of coefficients K, x, a, and n of Eq. 2.15. Some typical values of the coefficients for a few places in India are given in Table 2.6. Table 2.6 Typical values of Coefficients K, x, a and n in Eq. (2.15) [Ref. 10] Zone

Place

Northern Zone

Allahabad Amritsar Dehradun Jodhpur Srinagar Average for the zone Bhopal Nagpur Raipur Average for the zone Aurangabad Bhuj

Central Zone

Western Zone

K

x

a

n

4.911 14.41 6.00 4.098 1.503 5.914 6.9296 11.45 4.683 7.4645 6.081 3.823

0.1667 0.1304 0.22 0.1677 0.2730 0.1623 0.1892 0.1560 0. 1389 0.1712 0.1459 0.1919

0.25 1.40 0.50 0.50 0.25 0.50 0.50 1.25 0.15 0.75 0.50 0.25

0.6293 1.2963 0.8000 1.0369 1.0636 1.0127 0.8767 1.0324 0.9284 0.9599 1.0923 0.9902 (Contd.)

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Engineering Hydrology

(Contd.)

Eastern Zone

Southern Zone

Veraval Average for the zone Agarthala Kolkata (Dumdum) Gauhati Jarsuguda Average for the zone Bangalore Hyderabad Chennai Trivandrum Average for the zone

7.787 3.974 8.097 5.940 7.206 8.596 6.933 6.275 5.250 6.126 6.762 6.311

0.2087 0.1647 0.1177 0.1150 0.1157 0.1392 0.1353 0.1262 0.1354 0.1664 0.1536 0.1523

0.50 0.15 0.50 0.15 0.75 0.75 0.50 0.50 0.50 0.50 0.50 0.50

0.8908 0.7327 0.8191 0.9241 0.9401 0.8740 0.8801 1.1280 1.0295 0.8027 0.8158 0.9465

Extreme point rainfall values of different durations and for different return periods have been evaluated by IMD and the iso-pluvial (lines connecting equal depths of rainfall) maps covering the entire country have been prepared. These are available for rainfall durations of 15 min, 30 min, 45 min, 1 h, 3 h, 6 h, 9 h, 15 h and 24 h for return periods of 2, 5, 10, 25, 50 and 100 years. A typical 50 year–24 h maximum rainfall map of the southern peninsula is given in Fig. 2.21. The 50 year-l h maximum rainfall

Fig. 2.21 Isopluvial Map of 50 yr-24 h Maximum Rainfall (mm) (Reproduced with permission from India Meteorological Department) Based upon Survey of India map with the permission of the Surveyor General of India, © Government of India Copyright 1984 The territorial waters of India extend into the sea to a distance of 200 nautical miles measured from the appropriate baseline Responsibility for the correctness of the internal details on the map rests with the publisher.

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depths over India and the neighbourhood are shown in Fig. 2.22. Isopluvial maps of the maximum rainfall of various durations and of 50-year return periods covering the entire country are available in Ref. 1.

Fig. 2.22 Isopluvial Map of 50 yr-l h Maximum Rainfall (mm) (Reproduced from Natural Resources of Humid Tropical Asia—Natural Resources Research, XII. © UNESCO, 1974, with permission of UNESCO) Based upon Survey of India map with the permission of the Surveyor General of India © Government of India Copyright 1984 The territorial waters of India extend into the sea to a distance of 200 nautical miles measured from the appropriate baseline Responsibility for the correctness of the internal details on the map rests with the publisher.

EXAMPLE 2.9 The mass curve of rainfall in a storm of total duration 270 minutes is given below. (a) Draw the hyetograph of the storm at 30 minutes time step. (b) Plot the maximum intensity-duration curve for this storm. (c) Plot the maximum depth-duration curve for the storm. Times since Start in Minutes 0 Cumulative Rainfall (mm) 0

30 6

60 18

90 21

120 150 180 210 240 270 36 43 49 52 53 54

SOLUTION: (a) Hyetograph: The intensity of rainfall at various time durations is calculated as shown below:

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Engineering Hydrology

Time since Start (min) Cumulative Rainfall (mm) Incremental depth of rainfall in the interval (mm) Intensity (mm/h)

30 60 90 120 150 180 210 240 270 6.0 18.0 21.0 36.0 43.0 49.0 52.0 53.0 54.0 6.0 12.0 12.0 24.0

3.0 15.0 7.0 6.0 6.0 30.0 14.0 12.0

3.0 6.0

1.0 2.0

1.0 2.0

The hyetograph of the storm is shown in Fig. 2.23

Fig. 2.23 Hyetograph of the Storm—Example 2.9 (b) Various durations Dt = 30, 60, 90 … 240, 270 minutes are chosen. For each duration Dt a series of running totals of rainfall depth is obtained by starting from various points of the mass curve. This can be done systematically as shown in Table 2.7(a & b). By inspection the maximum depth for each tj is identified and corresponding maximum intensity is calculated. In Table 2.7(a) the maximum depth is marked by bold letter and maximum intensity corresponding to a specified duration is shown in Row No. 3 of Table 2.7(b). The data obtained from the above analysis is plotted as maximum depth vs duration and maximum intensity vs duration as shown in Fig. 2.24.

2.13 PROBABLE MAXIMUM PRECIPITATION (PMP) In the design of major hydraulic structures such as spillways in large dams, the hydrologist and hydraulic engineer would like to keep the failure probability as low as possible, i.e. virtually zero. This is because the failure of such a major structure will cause very heavy damages to life, property, economy and national morale. In the design and analysis of such structures, the maximum possible precipitation that can reasonably be expected at a given location is used. This stems from the recognition that there is a physical upper limit to the amount of precipitation that can fall over a specified area in a given time.

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Table 2.7(a) Maximum Intensity-Duration Relation Incremental depth of rainfall (mm) in various durations Cumulative Time Rainfall (min.) (mm)

Durations(min) 30

60

90

0 30 60 90

0 6 18 21

6 12 3

18 15

21

120 150 180 210 240 270

36 43 49 52 53 54

15 7 6 3 1 1

18 22 13 9 4 2

30 25 28 16 10 5

120

150

180

210

240

270

36 37 31 31 17 11

43 43 34 32 18

49 46 35 33

52 47 36

53 48

54

Table 2.7(b) Maximum Intensity-Maximum Depth-Duration Relation Maximum Intensity (mm/h) Duration in min. Maximum Depth (mm)

30.0

22.0

20.0

30

60

90

15.0

22.0

30.0

18.5 120 37.0

17.2 150 43.0

16.3 180 49.0

14.9 210 52.0

13.3 240 53.0

12.0 270 54.0

Fig. 2.24 Maximum Intensity-Duration and Maximum Depth-Duration Curves for the Storm of Example 2.9 The probable maximum precipitation (PMP) is defined as the greatest or extreme rainfall for a given duration that is physically possible over a station or basin. From the operational point of view, PMP can be defined as that rainfall over a basin which

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Engineering Hydrology

would produce a flood flow with virtually no risk of being exceeded. The development of PMP for a given region is an involved procedure and requires the knowledge of an experienced hydrometeorologist. Basically two approaches are used (i) Meteorological methods and (ii) the statistical study of rainfall data. Details of meteorological methods that use storm models are available in published literature.8 Statistical studies indicate that PMP can be estimated as PMP = P + KI (2.16) where P = mean of annual maximum rainfall series, I = standard deviation of the series and K = a frequency factor which depends upon the statistical distribution of the series, number of years of record and the return period. The value of K is usually in the neighbourhood of 15. Generalised charts for one-day PMP prepared on the basis of the statistical analysis of 60 to 70 years of rainfall data in the North-Indian plain area (Lat. 20° N to 32° N, Long. 68° E to 89° E) are available in Refs 4 and 5. It is found that PMP estimates for North-Indian plains vary from 37 to 100 cm for one-day rainfall. Maps depicting isolines of 1-day PMP over different parts of India are available in the PMP atlas published by the Indian Institute of Tropical Meteorology.6

World’s Greatest Observed Rainfall Based upon the rainfall records available all over the world, a list of world’s greatest recorded rainfalls of various duration can be assembled. When this data is plotted on a log-log paper, an enveloping straight line drawn to the plotted points obeys the equation. Pm = 42.16 D0.475 (2.17) where Pm = extreme rainfall depth in cm and D = duration in hours. The values obtained from this Eq. (2.17) are of use in PMP estimations.

2.14 RAINFALL DATA IN INDIA Rainfall measurement in India began in the eighteenth century. The first recorded data were obtained at Calcutta (1784) and it was followed by observations at Madras (1792), Bombay (1823) and Simla (1840). The India Meteorological Department (IMD) was established in 1875 and the rainfall resolution of the Government of India in 1930 empowered IMD to have overall technical control of rainfall registration in the country. According to this resolution, which is still the basis, the recording, collection and publication of rainfall data is the responsibility of the state government whereas the technical control is under IMD. The state government have the obligation to supply daily, monthly and annual rainfall data to IMD for compilation of its two important annual publications entitled Daily Rainfall of India and Monthly Rainfall of India. India has a network of observatories and rain gauges maintained by IMD. Currently (2005), IMD has 701 hydrometeorological observatories and 201 agrometeorological observatories. In addition there are 8579 rain gauge stations out of which 3540 stations report their data to IMD. A fair amount of these gauges are of self-recording type and IMD operates nearly 400 self-recording rain gauges. A set of 21 snow gauges, 10 ordinary rain gauges and 6 seasonal snow poles form part of glaciological observatories of the country. In addition to the above, a large number of rain gauges are maintained by different governmental agencies such as Railways, State departments of Agriculture, Forestry and Irrigation and also by private agencies like coffee and tea plantations. Data from these stations though recorded regularly are not published and as such are not easily available for hydrological studies.

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REFERENCES 1. Central Water Commission, India, Estimation of Design Flood Peak, Flood Estimation Directorate, Report No. 1/73, New Delhi, 1973. 2. Chow, V.T. (Ed), Handbook of Applied Hydrology, McGraw-Hill, New York, N.Y., 1964. 3. Dhar, O.N. and B.K. Bhattacharya, “A study of depth area duration statistics of the severemost storms over different meteorological divisions of North India”, Proc. Nat. Symp on Hydrology, Roorkee, India, 1975, pp. G-4–11. 4. Dhar, O.N. and A.K. Kulkarni, “Estimation of probable maximum, precipitation for some selected stations in and near Himalayas”, Proc. Nat. Symp. on Hydrology, Roorkee, India, 1975, pp. G-12–16. 5. Dhar, O.N. and P. Rakecha. “A review of hydrometeorological studies of Indian rainfall”, Proc. 2nd World Congress on Water Resources, New Delhi, Vol. III, 1975, pp. 449–462. 6. Indian Institute of Tropical Meteorology, Probable Maximum Precipitation Atlas, IITM, Pune, India, March 1989. 7. Rakecha, P.K. and Deshpande, N.R., Precipitation Network Design, Jal Vigyan Sameeksha (Hydrology Review), Vol. II, No. 2, Dec. 1987, pp. 56–75. 8. Weisner, C.J., Hydrometeorolgy, Chapman and Hall, London, 1970. 9. World Meteorological Organisation, Manual for Depth-Area-Duration Analysis of Storm Precipitation, WMO No. 237, TP 129, Geneva, Switzerland, 1969. 10. Ram Babu et al. Rainfall Intensity-Duration-Return Period Equations and Nomographs of India, Bull. No. 3, CSWCRTI, Dehradun, India, 1979.

REVISION QUESTIONS 2.1 2.2 2.3 2.4 2.5 2.6 2.7

2.8 2.9

Describe the different methods of recording of rainfall. Discuss the current practice and status of rainfall recording in India. Describe the salient characteristics of precipitation on India. Explain the different methods of determining the average rainfall over a catchment due to a storm. Discuss the relative merits and demerits of the various methods. Explain a procedure for checking a rainfall data for consistency. Explain a procedure for supplementing the missing rainfall data. Explain briefly the following relationships relating to the precipitation over a basin: (a) Depth-Area Relationship (b) Maximum Depth-Area-Duration Curves (c) Intensity Duration Frequency Relationship. What is meant by Probable Maximum Precipitation (PMP) over a basin? Explain how PMP is estimated. Consider the statement: The 50 year-24 hour maximum rainfall at Bangalore is 160 mm. What do you understand by this statement?

PROBLEMS 2.1 A catchment area has seven raingauge stations. In a year the annual rainfall recorded by the gauges are as follows: Station Rainfall (cm)

P 130.0

Q 142.1

R 118.2

S 108.5

T 165.2

U 102.1

V 146.9

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Engineering Hydrology

For a 5% error in the estimation of the mean rainfall, calculate the minimum number of additional stations required to be established in the catchment. 2.2 The normal annual precipitation of five raingauge stations P, Q, R, S and T are respectively 125, 102, 76, 113 and 137 cm. During a particular storm the precipitation recorded by stations P, Q, R, and S are 13.2, 9.2, 6.8 and 10.2 cm respectively. The instrument at station T was inoperative during that storm. Estimate the rainfall at station T during that storm. 2.3 Test the consistency of the 22 years of data of the annual precipitation measured at station A. Rainfall data for station A as well as the average annual rainfall measured at a group of eight neighbouring stations located in a meteorologically homogeneous region are given as follows.

Year

1946 1947 1948 1949 1950 1951 1952 1953 1954 1955 1956

Annual Rainfall of Station A (mm)

Average Annual Rainfall of 8 Station groups (mm)

Year

177 144 178 162 194 168 196 144 160 196 141

143 132 146 147 161 155 152 117 128 193 156

1957 1958 1959 1960 1961 1962 1963 1964 1965 1966 1967

Annual Rainfall of Station A (mm)

Average Annual Rainfall of 8 Station groups (mm)

158 145 132 95 148 142 140 130 137 130 163

164 155 143 115 135 163 135 143 130 146 161

(a) In what year is a change in regime indicated? (b) Adjust the recorded data at station A and determine the mean annual precipitation. 2.4 In a storm of 210 minutes duration, the incremental rainfall at various time intervals is given below. Time since start of the storm (minutes) Incremental rainfall in the time interval (cm)

30

60

90

120

150

180

210

1.75

2.25

6.00

4.50

2.50

1.50

0.75

(a) Obtain the ordinates of the hyetograph and represent the hyetograph as a bar chart with time in chronological order in the x-axis. (b) Obtain the ordinates of the mass curve of rainfall for this storm and plot the same. What is the average intensity of storm over the duration of the storm? 2.5 Assuming the density of water as 998 kg/m3, determine the internal diameter of a tubular snow sample such that 0.1 N of snow in the sample represents 10 mm of water equivalent. 2.6 Represent the annual rainfall data of station A given below as a bar chart with time in chronological order. If the annual rainfall less than 75% of long term mean is taken to signify meteorological drought, identify the drought years and suitably display the same in the bar chart.

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Year 1961 1962 1963 1964 1965 1966 1967 1968 1969 1970 Annual rain (mm) 760 750 427 380 480 620 550 640 624 500 Year 1971 1972 1973 1974 1975 1976 1977 1978 1979 1980 Annual rain (mm) 400 356 700 580 520 102 525 900 600 400 2.7

For a drainage basin of 600 km2, isohyetals drawn for a storm gave the following data: Isohyetals (interval) (cm) Inter-isohyetal area (km2)

2.8

15–12 92

12–9 128

9–6 120

6–3 175

3–1 85

Estimate the average depth of precipitation over the catchment. There are 10 raingauge stations available to calculate the rainfall characteristics of a catchment whose shape can be approximately described by straight lines joining the following coordinates (distances in kilometres): (30, 0), (80, 10), (110, 30), (140, 90), (130, 115), (40, 110), (15, 60). Coordinates of the raingauge stations and the annual rainfall recorded in them in the year 1981 are given below. Station Co-ordinates Annual Rainfall (cm) Station Co-ordinates Annual Rainfall (cm)

1

2

3

4

5

(0, 40)

(50, 0)

(140, 30)

(140, 80)

(90, 140)

132 6 (0, 80)

136 7 (40, 50)

93 8 (90, 30)

81 9 (90, 90)

85 10 (40, 80)

124

156

128

102

128

Determine the average annual rainfall over the catchment. Figure 2.25 shows a catchment with seven raingauge stations inside it and three stations outside. The rainfall recorded by each of these stations are indicated in the figure. Draw the figure to an enlarged scale and calculate the mean precipitation by (a) Thiessenmean method, (b) Isohyetal method and by (c) Arithmetic-mean method. 2.10 Annual rainfall at a point M is needed. At five points surrounding the point M the values of recorded rainfall together with the coordinates of these stations with respect to a set of axes at point M are given below. Estimate the annual rainfall at point M by using the USNWS method. 2.9

Station

Rainfall P (cm)

A B C D E

102 120 126 108 131

Coordinates of station (in units) X Y 2.0 2.0 3.0 1.5 4.5

1.0 2.0 1.0 1.0 1.5

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Engineering Hydrology

Fig. 2.25 Problem 2.9

é Hint: In the US National Weather Service (USNWS) method the weightage to the êë

stations are inversely proportional to the square of the distance of the station from the station M. If the co-ordinate of any station is (x, y) then D2 = x2 + y2 and weightage

SPW ù . SW úû 2.11 Estimate from depth-area curve, the average depth of precipitation that may be expected over an area of 2400 Sq. km due to the storm of 27th September 1978 which lasted for 24 hours. Assume the storm centre to be located at the centre of the area. The isohyetal map for the storm gave the areas enclosed between different isohyetes as follows: W = 1/D2. Then rainfall at M = Pm =

Isohyet (mm) Enclosed area (km2)

21 54 3

20 134 5

19 203 0

18 254 5

17 295 5

16 328 0

15 353 5

14 371 0

13 388 0

12 391 5

2.12 Following are the data of a storm as recorded in a self-recording rain gauge at a station: Time from the beginning of storm (minutes) Cumulative rainfall (mm)

10 19

20 41

30 48

40 68

50 91

60 70 80 90 124 152 160 166

(a) Plot the hyetograph of the storm. (b) Plot the maximum intensity-duration curve of the storm. 2.13 Prepare the Maximum depth-duration curve for the 90 minute storm given below: Time (minutes) Cumulative rainfall (mm)

0 0

10 8

20 15

30 25

40 30

50 46

60 55

70 60

80 64

90 67

Precipitation

##

2.14 The mass curve of rainfall in a storm of total duration 90 minutes is given below. (a) Draw the hyetograph of the storm at 10 minutes time step. (b) Plot the Maximum intensity-duration curve for this storm. (c) Plot the Maximum depth-duration curve for the storm. Time (Minutes) Cumulative rainfall (mm)

10

20

30

40

50

60

70

2.1

6.3

14.5

21.7

27.9

33.0

35.1

80

90

36.2 37.0

2.15 The record of annual rainfall at a place is available for 25 years. Plot the curve of recurrence interval vs annual rainfall magnitude and by suitable interpolation estimate the magnitude of rainfall at the station that would correspond to a recurrence interval of (a) 50 years and (b) 100 years.

Year

Annual Rainfall (cm)

Year

1950 1951 1952 1953 1954 1955 1956 1957 1958 1959 1960 1961 1962

113.0 94.5 76.0 87.5 92.7 71.3 77.3 85.1 122.8 69.4 81.0 94.5 86.3

1963 1964 1965 1966 1967 1968 1969 1970 1971 1972 1973 1974

Annual Rainfall (cm) 68.6 82.5 90.7 99.8 74.4 66.6 65.0 91.0 106.8 102.2 87.0 84.0

2.16 The annual rainfall values at a station P for a period of 20 years are as follows: Year

Annual Rainfall (cm)

Year

1975 1976 1977 1978 1979 1980 1981 1982 1983 1984

120.0 84.0 68.0 92.0 102.0 92.0 95.0 88.0 76.0 84.0

1985 1986 1987 1988 1989 1990 1991 1992 1993 1994

Annual Rainfall (cm) 101.0 109.0 106.0 115.0 95.0 90.0 70.0 89.0 80.0 90.0

Determine (a) The value of annual rainfall at P with a recurrence interval of 15 years. (b) The probability of occurrence of an annual rainfall of magnitude 100 cm at station P. (c) 75% dependable annual rainfall at the station. [Hint: If an event (rainfall magnitude in the present case) occurs more than once, the rank m = number of times the event is equalled + number of times it is exceeded.]

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Engineering Hydrology

2.17 Plot the three-year and the five-year moving means for the data of Problem 2.15. Comment on the effect of increase in the period of the moving mean. Is there any apparent trend in the data? 2.18 On the basis of isopluvial maps the 50 year-24 hour maximum rainfall at Bangalore is found to be 16.0 cm. Determine the probability of a 24 h rainfall of magnitude 16.0 cm occurring at Bangalore: (a) Once in ten successive years. (b) Twice in ten successive years. (c) At least once in ten successive years. 2.19 A one-day rainfall of 20.0 cm at a place X was found to have a period of 100 years. Calculate the probability that a one-day rainfall of magnitude equal to or larger than 20.0 cm: (a) Will not occur at station X during the next 50 years. (b) Will occur in the next year. 2.20 When long records are not available, records at two or more stations are combined to get one long record for the purposes of recurrence interval calculation. This method is known as Station-year method. The number of times a storm of intensity 6 cm/h was equalled or exceeded in three different rain gauge stations in a region were 4, 2 and 5 for periods of records of 36, 25 and 48 years. Find the recurrence interval of the 6 cm/h storm in that area by the station– year method. 2.21 Annual precipitation values at a place having 70 years of record can be tabulated as follows: Range (cm)

Number of years

< 60.0 60.0–79.9 80.0–99.9 100.0–119.9 120.0–139.9 > 140.0

6 6 22 25 8 3

Calculate the probability of having: (a) an annual rainfall equal to or larger than 120 cm, (b) two successive years in which the annual rainfall is equal to or greater than 140 cm, (c) an annual rainfall less than 60 cm.

OBJECTIVE QUESTIONS 2.1 A tropical cyclone is a (a) low-pressure zone that occurs in the northern hemisphere only (b) high-pressure zone with high winds (c) zone of low pressure with clockwise winds in the northern hemisphere (d) zone of low pressure with anticlockwise winds in the northern hemisphere. 2.2 A tropical cyclone in the northern hemisphere is a zone of (a) low pressure with clockwise wind (b) low pressure with anticlockwise wind (c) high pressure with clockwise wind (d) high pressure with anticlockwise wind.

Precipitation 2.3

2.4 2.5 2.6 2.7 2.8

2.9 2.10

2.11

2.12

2.13

2.14 2.15

#%

Orographic precipitation occurs due to air masses being lifted to higher altitudes by (a) the density difference of air masses (b) a frontal action (c) the presence of mountain barriers (d) extratropical cyclones. The average annual rainfall over the whole of India is estimated as (a) 189 cm (b) 319 cm (c) 89 cm (d) 117 cm. Variability of annual rainfall in India is (a) least in regions of scanty rainfall (b) largest in regions of high rainfall (c) least in regions of high rainfall (d) largest in coastal areas. The standard Symons’ type raingauge has a collecting area of diameter (a) 12.7 cm (b) 10 cm (c) 5.08 cm (d) 25.4 cm. The standard recording raingauge adopted in India is of (a) weighing bucket type (b) natural siphon type (c) tipping bucket type (d) telemetry type The following recording raingauges does not produce the mass curve of precipitation as record: (a) Symons’ raingauge (b) tipping-bucket type gauge (c) weighing-bucket type gauge (d) natural siphon gauge. When specific information about the density of snowfall is not available, the water equivalent of snowfall is taken as (a) 50% (b) 30% (c) 10% (d) 90% The normal annual rainfall at stations A, B and C situated in meteorologically homogeneous region are 175 cm, 180 cm and 150 cm respectively. In the year 2000, station B was inoperative and stations A and C recorded annual precipitations of 150 cm and 135 cm respectively. The annual rainfall at station B in that year could be estimated to be nearly (a) 150 cm (b) 143 cm (c) 158 cm (d) 168 cm The monthly rainfall at a place A during September 1982 was recorded as 55 mm above normal. Here the term normal means (a) the rainfall in the same month in the previous year (b) the rainfall was normally expected based on previous month’s data (c) the average rainfall computed from past 12 months’ record (d) The average monthly rainfall for September computed from a specific 30 years of past record. The Double mass curve technique is adopted to (a) check the consistency of raingauge records (b) to find the average rainfall over a number of years (c) to find the number of rainguages required (d) to estimate the missing rainfall data The mass curve of rainfall of a storm is a plot of (a) rainfall depths for various equal durations plotted in decreasing order (b) rainfall intensity vs time in chronological order (c) accumulated rainfall intensity vs time (d) accumulated precipitation vs time in chronological order. A plot between rainfall intensity vs time is called as (a) hydrograph (b) mass curve (c) hyetograph (d) isohyet A hyetograph is a plot of (a) Cumulative rainfall vs time (b) rainfall intensity vs time (c) rainfall depth vs duration (d) discharge vs time

#&

Engineering Hydrology

2.16 The Thiessen polygon is (a) a polygon obtained by joining adjoining raingauge stations (b) a representative area used for weighing the observed station precipitation (c) an area used in the construction of depth-area curves (d) the descriptive term for the shape of a hydrograph. 2.17 An isohyet is a line joining points having (a) equal evaporation value (b) equal barometric pressure (c) equal height above the MSL (d) equal rainfall depth in a given duration. 2.18 By DAD analysis the maximum average depth over an area of 104 km2 due to one-day storm is found to be 47 cm. For the same area the maximum average depth for a three day storm can be expected to be (a) < 47 cm (b) > 47 cm (c) = 47 cm (d) inadequate information to conclude. 2.19 Depth-Area-Duration curves of precipitation are drawn as (a) minimizing envelopes through the appropriate data points (b) maximising envelopes through the appropriate data point (c) best fit mean curves through the appropriate data points (d) best fit straight lines through the appropriate data points 2.20 Depth-Area-Duration curves of precipitation at a station would normally be (a) curves, concave upwards, with duration increasing outward (b) curves, concave downwards, with duration increasing outward (c) curves, concave upwards, with duration decreasing outward (d) curves, concave downwards, with duration decreasing outward 2.21 A study of the isopluvial maps revealed that at Calcutta a maximum rainfall depth of 200 mm in 12 h has a return period of 50 years. The probability of a 12 h rainfall equal to or greater than 200 mm occurring at Calcutta at least once in 30 years is (a) 0.45 (b) 0.60 (c) 0.56 (d) 1.0 2.22 A 6-h rainfall of 6 cm at a place A was found to have a return period of 40 years. The probability that at A a 6-h rainfall of this or larger magnitude will occur at least once in 20 successive years is (a) 0.397 (b) 0.603 (c) 0.309 (d) 0.025 2.23 The probability of a 10 cm rain in 1 hour occurring at a station B is found to be 1/60. What is the probability that a 1 hour rain of magnitude 10 cm or larger will occur in station B once in 30 successive years is (a) 0.396 (b) 0.307 (c) 0.604 (d) 0.500 2.24 A one day rainfall of 18 hours at Station C was found to have a return period of 50 years. The probability that a one-day rainfall of this or larger magnitude will not occur at station C during next 50 years is (a) 0.636 (b) 0.020 (c) 0.364 (d) 0.371 2.25 If the maximum depth of a 50 years-15 h-rainfall depth at Bhubaneshwar is 260 mm, the 50 year-3 h-maximum rainfall depth at the same place is (a) < 260 mm (b) > 260 mm (c) = 260 mm (d) inadequate date to conclude anything. 2.26 The probable maximum depth of precipitation over a catchment is given by the relation PMP = (a) P + KAn

(b) P + K I

(c) P exp (–K An)

(d) mP

Chapter

3

ABSTRACTIONS FROM PRECIPITATION

3.1 INTRODUCTION In Engineering Hydrology runoff due to a storm event is often the major subject of study. All abstractions from precipitation, viz. those due to evaporation, transpiration, infiltration, surface detention and storage, are considered as losses in the production of runoff. Chief components of abstractions from precipitation, knowledge of which are necessary in the analysis of various hydrologic situations, are described in this chapter. Evaporation from water bodies and soil masses together with transpiration from vegetation is termed as evapotranspiration. Various aspects of evaporation from water bodies and evapotranspiration from a basin are discussed in detail in Secs 3.2 through 3.11. Interception and depression storages, which act as ‘losses’ in the production of runoff, are discussed in Secs 3.12 and 3.13. Infiltration process, which is a major abstraction from precipitation and an important process in groundwater recharge and in increasing soil moisture storage, is described in detail in Secs 3.14 through 3.19.

A: EVAPORATION 3.2 EVAPORATION PROCESS Evaporation is the process in which a liquid changes to the gaseous state at the free surface, below the boiling point through the transfer of heat energy. Consider a body of water in a pond. The molecules of water are in constant motion with a wide range of instantaneous velocities. An addition of heat causes this range and average speed to increase. When some molecules possess sufficient kinetic energy, they may cross over the water surface. Similarly, the atmosphere in the immediate neighbourhood of the water surface contains water molecules within the water vapour in motion and some of them may penetrate the water surface. The net escape of water molecules from the liquid state to the gaseous state constitutes evaporation. Evaporation is a cooling process in that the latent heat of vaporization (at about 585 cal/g of evaporated water) must be provided by the water body. The rate of evaporation is dependent on (i) the vapour pressures at the water surface and air above, (ii) air and water temperatures, (iii) wind speed, (iv) atmospheric pressure, (v) quality of water, and (vi) size of the water body. Vapour Pressure The rate of evaporation is proportional to the difference between the saturation vapour pressure at the water temperature, ew and the actual vapour pressure in the air, ea. Thus EL = C(ew – ea ) (3.1)

60

Engineering Hydrology

where EL = rate of evaporation (mm/day) and C = a constant; ew and ea are in mm of mercury. Equation (3.1) is known as Dalton’s law of evaporation after John Dalton (1802) who first recognised this law. Evaporation continues till ew = ea. If ew > ea condensation takes place. Temperature Other factors remaining the same, the rate of evaporation increases with an increase in the water temperature. Regarding air temperature, although there is a general increase in the evaporation rate with increasing temperature, a high correlation between evaporation rate and air temperature does not exist. Thus for the same mean monthly temperature it is possible to have evaporation to different degrees in a lake in different months. Wind Wind aids in removing the evaporated water vapour from the zone of evaporation and consequently creates greater scope for evaporation. However, if the wind velocity is large enough to remove all the evaporated water vapour, any further increase in wind velocity does not influence the evaporation. Thus the rate of evaporation increases with the wind speed up to a critical speed beyond which any further increase in the wind speed has no influence on the evaporation rate. This critical windspeed value is a function of the size of the water surface. For large water bodies highspeed turbulent winds are needed to cause maximum rate of evaporation. Atmospheric Pressure Other factors remaining same, a decrease in the barometric pressure, as in high altitudes, increases evaporation. Soluble Salts When a solute is dissolved in water, the vapour pressure of the solution is less than that of pure water and hence causes reduction in the rate of evaporation. The percent reduction in evaporation approximately corresponds to the percentage increase in the specific gravity. Thus, for example, under identical conditions evaporation from sea water is about 2–3% less than that from fresh water. Heat Storage in Water Bodies Deep water bodies have more heat storage than shallow ones. A deep lake may store radiation energy received in summer and release it in winter causing less evaporation in summer and more evaporation in winter compared to a shallow lake exposed to a similar situation. However, the effect of heat storage is essentially to change the seasonal evaporation rates and the annual evaporation rate is seldom affected.

3.3 EVAPORIMETERS Estimation of evaporation is of utmost importance in many hydrologic problems associated with planning and operation of reservoirs and irrigation systems. In arid zones, this estimation is particularly important to conserve the scarce water resources. However, the exact measurement of evaporation from a large body of water is indeed one of the most difficult tasks. The amount of water evaporated from a water surface is estimated by the following methods: (i) using evaporimeter data, (ii) empirical evaporation equations, and (iii) analytical methods.

Types of Evaporimeters Evaporimeters are water-containing pans which are exposed to the atmosphere and the loss of water by evaporation measured in them at regular intervals. Meteorological

Abstractions from Precipitation

61

data, such as humidity, wind movement, air and water temperatures and precipitation are also noted along with evaporation measurement. Many types of evaporimeters are in use and a few commonly used pans are described here. Class A Evaporation Pan It is a standard pan of 1210 mm diameter and 255 mm depth used by the US Weather Bureau and is known as Class A Land Pan. The depth of water is maintained between 18 cm and 20 cm (Fig. 3.1). The pan is normally made of unpainted galvanised iron sheet. Fig. 3.1 U.S. Class A Evaporation Pan Monel metal is used where corrosion is a problem. The pan is placed on a wooden platform of 15 cm height above the ground to allow free circulation of air below the pan. Evaporation measurements are made by measuring the depth of water with a hook gauge in a stilling well. ISI Standard Pan This pan evaporimeter specified by IS: 5973–1970, also known as modified Class A Pan, consists of a pan 1220 mm in diameter with 255 mm of depth. The pan is made of copper sheet of 0.9 mm thickness, tinned inside and painted white outside (Fig. 3.2). A fixed point gauge indicates the level of water. A calibrated cylindrical measure is used to add or remove water maintaining the water level in the pan to a fixed mark. The top of the pan is covered fully with a hexagonal wire netting of galvanized iron to protect the water in the pan from birds. Further, the presence of a wire mesh makes the water temperature more uniform during day and night. The evaporation from this pan is found to be less by about 14% compared to that from unscreened pan. The pan is placed over a square wooden platform of 1225 mm width and 100 mm height to enable circulation of air underneath the pan.

Fig. 3.2 ISI Evaporation Pan

62

Engineering Hydrology

Colorado Sunken Pan This pan, 920 mm square and 460 mm deep is made up of unpainted galvanised iron sheet and buried into the ground within 100 mm of the top (Fig. 3.3). The chief advantage of the sunken pan is that radiation and aerodynamic characteristics are similar to those of a lake. However, it has the followFig. 3.3 Colorado Sunken Evaporation Pan ing disadvantages: (i) difficult to detect leaks, (ii) extra care is needed to keep the surrounding area free from tall grass, dust, etc., and (iii) expensive to instal. US Geological Survey Floating Pan With a view to simulate the characteristics of a large body of water, this square pan (900 mm side and 450 mm depth) supported by drum floats in the middle of a raft (4.25 m ´ 4.87 m) is set afloat in a lake. The water level in the pan is kept at the same level as the lake leaving a rim of 75 mm. Diagonal baffles provided in the pan reduce the surging in the pan due to wave action. Its high cost of installation and maintenance together with the difficulty involved in performing measurements are its main disadvantages. Pan Coefficient Cp Evaporation pans are not exact models of large reservoirs and have the following principal drawbacks: 1. They differ in the heat-storing capacity and heat transfer from the sides and bottom. The sunken pan and floating pan aim to reduce this deficiency. As a result of this factor the evaporation from a pan depends to a certain extent on its size. While a pan of 3 m diameter is known to give a value which is about the same as from a neighbouring large lake, a pan of size 1.0 m diameter indicates about 20% excess evaporation than that of the 3 m diameter pan. 2. The height of the rim in an evaporation pan affects the wind action over the surface. Also, it casts a shadow of variable magnitude over the water surface. 3. The heat-transfer characteristics of the pan material is different from that of the reservoir. In view of the above, the evaporation observed from a pan has to be corrected to get the evaporation from a lake under similar climatic and exposure conditions. Thus a coefficient is introduced as Lake evaporation = Cp ´ pan evaporation in which Cp = pan coefficient. The values of Cp in use for different pans are given in Table 3.l. Table 3.1 Values of Pan Coefficient Cp S.No. 1. 2. 3. 4.

Types of pan Class A Land Pan ISI Pan (modified Class A) Colorado Sunken Pan USGS Floating Pan

Average value

Range

0.70 0.80 0.78 0.80

0.60–0.80 0.65–1.10 0.75–0.86 0.70–0.82

Abstractions from Precipitation

63

Evaporation Stations It is usual to instal evaporation pans in such locations where other meteorological data are also simultaneously collected. The WMO recommends the minimum network of evaporimeter stations as below: 1. Arid zones—One station for every 30,000 km2, 2. Humid temperate climates—One station for every 50,000 km2, and 3. Cold regions—One station for every 100,000 km2. Currently, about 220 pan-evaporimeter stations are being maintained by India Meteorological Department. A typical hydrometeorological station contains the following: Ordinary raingauge; Recording raingauge; Stevenson Box with maximum and minimum thermometer and dry and wet bulb thermometers; wind anemometer, wind direction indicator, sunshine recorder, thermohydrograph and pan evaporimeter.

3.4 EMPIRICAL EVAPORATION EQUATIONS A large number of empirical equations are available to estimate lake evaporation using commonly available meteorological data. Most formulae are based on the Daltontype equation and can be expressed in the general form EL = K f (u)(ew – ea) (3.2) where EL = lake evaporation in mm/day, ew = saturated vapour pressure at the watersurface temperature in mm of mercury, ea = actual vapour pressure of over-lying air at a specified height in mm of mercury, f (u) = wind-speed correction function and K = a coefficient. The term ea is measured at the same height at which wind speed is measured. Two commonly used empirical evaporation formulae are: Meyer’s Formula (1915)

u9 ö æ EL = KM (ew – ea ) ç1 + ÷ (3.3) è 16 ø in which EL, ew, ea are as defined in Eq. (3.2), u9 = monthly mean wind velocity in km/ h at about 9 m above ground and KM = coefficient accounting for various other factors with a value of 0.36 for large deep waters and 0.50 for small, shallow waters. Rohwer’s Formula (1931) Rohwer’s formula considers a correction for the effect of pressure in addition to the wind-speed effect and is given by EL = 0.771(1.465 – 0.000732 pa )(0.44 + 0.0733 u0) (ew – ea ) (3.4) in which EL, ew, and ea are as defined earlier in Eq. (3.2), pa = mean barometric reading in mm of mercury u0 = mean wind velocity in km/h at ground level, which can be taken to be the velocity at 0.6 m height above ground. These empirical formulae are simple to use and permit the use of standard meteorological data. However, in view of the various limitations of the formulae, they can at best be expected to give an approximate magnitude of the evaporation. References 2 and 3 list several other popular empirical formulae. In using the empirical equations, the saturated vapour pressure at a given temperature (ew) is found from a table of ew vs temperature in °C, such as Table 3.3. Often, the wind-velocity data would be available at an elevation other than that needed in the particular equation. However, it is known that in the lower part of the atmosphere, up

64

Engineering Hydrology

to a height of about 500 m above the ground level, the wind velocity can be assumed to follow the 1/7 power law as uh = Ch1/7 (3.5) where uh = wind velocity at a height h above the ground and C = constant. This equation can be used to determine the velocity at any desired level if uh is known. EXAMPLE 3.1

(a) A reservoir with a surface area of 250 hectares had the following average values of climate parameters during a week: Water temperature = 20°C, Relative humidity = 40%, Wind velocity at 1.0 m above ground surface = 16 km/h. Estimate the average daily evaporation from the lake by using Meyer’s formula. (b) An ISI Standard evaporation pan at the site indicated a pan coefficient of 0.80 on the basis of calibration against controlled water budgeting method. If this pan indicated an evaporation of 72 mm in the week under question, (i) estimate the accuracy if Meyer’s method relative to the pan evaporation measurements. (ii) Also, estimate the volume of water evaporated from the lake in that week.

SOLUTION:

(a) From Table 3.3 ew = 17.54 mm of Hg ea = 0.4 ´ 17.54 = 7.02 mm of Hg u9 = wind velocity at a height of 9.0 m above ground = u1 ´ (9)1/7 = 21.9 km/h By Meyer’s Formula [Eq. (3.3)],

21.9 ö = 8.97 mm/day 16 ø 72.00 ö (b) (i) Daily evaporation as per Pan evaporimeter = æ ´ 0.8 = 8.23 mm è 7 ø EL = 0.36 (17.54 – 7.02) æ1 +

è

Error by Meyer’s formula = (8.23 – 8.97) = –0.74 mm. Hence, Meyer’s method overestimates the evaporation relative to the Pan. Percentage over estimation by Meyer’s formula = (0.74/8.23) ´ 100 = 9% (ii) Considering the Pan measurements as the basis, volume of water evaporated from the lake in 7 days = 7 ´ (8.23/1000) ´ 250 ´ 104 = 144,025 m3 [The lake area is assumed to be constant at 250 ha throughout the week.]

3.5

ANALYTICAL METHODS OF EVAPORATION ESTIMATION

The analytical methods for the determination of lake evaporation can be broadly classified into three categories as: 1. Water-budget method, 2. Energy-balance method, and 3. Mass-transfer method.

Water-Budget Method The water-budget method is the simplest of the three analytical methods and is also the least reliable. It involves writing the hydrological continuity equation for the lake and determining the evaporation from a knowledge or estimation of other variables. Thus considering the daily average values for a lake, the continuity equation is written as P + Vis + Vig = Vos + Vog +EL + DS + TL (3.6) where P = daily precipitation

Abstractions from Precipitation

65

Vis = daily surface inflow into the lake Vig = daily groundwater inflow Vos = daily surface outflow from the lake Vog = daily seepage outflow EL = daily lake evaporation DS = increase in lake storage in a day TL = daily transpiration loss All quantities are in units of volume (m3) or depth (mm) over a reference area. Equation (3.6) can be written as EL = P + (Vis – Vos) + (Vig – Vog) – TL – DS (3.7) In this the terms P, Vis, Vos and DS can be measured. However, it is not possible to measure Vig. Vog and TL and therefore these quantities can only be estimated. Transpiration losses can be considered to be insignificant in some reservoirs. If the unit of time is kept large, say weeks or months, better accuracy in the estimate of EL is possible. In view of the various uncertainties in the estimated values and the possibilities of errors in measured variables, the water-budget method cannot be expected to give very accurate results. However, controlled studies such as at Lake Hefner in USA (1952) have given fairly accurate results by this method.

Energy-Budget Method The energy-budget method is an application of the law of conservation of energy. The energy available for evaporation is determined by considering the incoming energy, outgoing energy and energy stored in the water body over a known time interval. Considering the water body as in Fig. 3.4, the energy balance to the evaporating surface in a period of one day is give by where

Hn = Ha + He + Hg + Hs + Hi Hn = net heat energy received by the water surface = Hc(1 – r) – Hb

Fig. 3.4 Energy Balance in a Water Body in which Hc(1 – r) = incoming solar radiation into a surface of reflection coefficient (albedo) r

(3.8)

66

Engineering Hydrology

Hb = back radiation (long wave) from water body Ha = sensible heat transfer from water surface to air He = heat energy used up in evaporation = r LEL, where r = density of water, L = latent heat of evaporation and EL = evaporation in mm Hg = heat flux into the ground Hs = heat stored in water body Hi = net heat conducted out of the system by water flow (advected energy) All the energy terms are in calories per square mm per day. If the time periods are short, the terms Hs and Hi can be neglected as negligibly small. All the terms except Ha can either be measured or evaluated indirectly. The sensible heat term Ha which cannot be readily measured is estimated using Bowen’s ratio b given by the expression Tw - Ta Ha b= = 6.1 ´ 10–4 ´ pa (3.9) ew - ea r LE L where pa = atmospheric pressure in mm of mercury, ew = saturated vapour pressure in mm of mercury, ea = actual vapour pressure of air in mm of mercury, Tw = temperature of water surface in °C and Ta = temperature of air in °C. From Eqs (3.8) and (3.9) EL can be evaluated as H n - H g - H s - Hi (3.10) EL = r L (1 + b ) Estimation of evaporation in a lake by the energy balance method has been found to give satisfactory results, with errors of the order of 5% when applied to periods less than a week. Further details of the energy-budget method are available in Refs 2, 3 and 5.

Mass-Transfer Method This method is based on theories of turbulent mass transfer in boundary layer to calculate the mass water vapour transfer from the surface to the surrounding atmosphere. However, the details of the method are beyond the scope of this book and can be found in published literature2, 5. With the use of quantities measured by sophisticated (and expensive) instrumentation, this method can give satisfactory results.

3.6 RESERVOIR EVAPORATION AND METHODS FOR ITS REDUCTION Any of the methods mentioned above may be used for the estimation of reservoir evaporation. Although analytical methods provide better results, they involve parameters that are difficult to assess or expensive to obtain. Empirical equations can at best give approximate values of the correct order of magnitude. Therefore, the pan measurements find general acceptance for practical application. Mean monthly and annual evaporation data collected by IMD are very valuable in field estimations. The water volume lost due to evaporation from a reservoir in a month is calculated as VE = A Epm Cp (3.11) 3 where VE = volume of water lost in evaporation in a month (m ) A = average reservoir area during the month (m2)

67

Abstractions from Precipitation

Epm = pan evaporation loss in metres in a month (m) = EL in mm/day ´ No. of days in the month ´ 10–3 Cp = relevant pan coefficient Evaporation from a water surface is a continuous process. Typically under Indian conditions, evaporation loss from a water body is about 160 cm in a year with enhanced values in arid regions. The quantity of stored water lost by evaporation in a year is indeed considerable as the surface area of many natural and man-made lakes in the country are very large. While a small sized tank (lake) may have a surface area of about 20 ha large reservoirs such as Narmada Sagar have surface area of about 90,000 ha. Table 3.2 (a) indicates surface areas and capacities of some large Indian reservoirs. Table 3.2(a) Surface Areas and Capacities of Some Indian Reservoirs Sl. No

1. 2. 3. 4. 5. 6. 7. 8. 9. 10.

Reservoir

Narmada Sagar Nagarjuna Sagar Sardar Sarovar Bhakra Hirakud Gandhi Sagar Tungabhadra Shivaji Sagar Kadana Panchet

River

Narmada Krishna Narmada Sutlej Mahanadi Chambal Tungabhadra Koyna Mahi Damodar

State

Surface Gross area at capacity of the MRL in reservoir in km2 Mm3

Madhya Pradesh Andhra Pradesh Gujarat Punjab Orissa Madhya Pradesh Karnataka Maharashtra Gujarat Jharkhand

914 285 370 169 725 660 378 115 172 153

12,230 11,315 9510 9868 8141 7746 4040 2780 1714 1497

Using evaporation data from 29 major and medium reservoirs in the country, the National Commission for integrated water resources development (1999)8 has estimated the national water loss due to evaporation at various time horizons as below: Table 3.2(b) Water Loss due to Evaporation (Volume in km3) Sl. No. 1. 2. 3. 4. 5.

Particular

1997

2010

2025

2050

Live Capacity–Major storage Live Capacity–Minor storage Evaporation for Major storage Reservoirs @ 15% of live capacity Evaporation for Minor storage Reservoirs @ 25% of live capacity Total Evaporation loss

173.7 34.7 26.1

211.4 42.3 31.7

249.2 49.8 37.4

381.5 76.3 57.2

8.7

10.6

12.5

19.1

42

50

76

35

Roughly, a quantity equivalent to entire live capacity of minor storages is lost annually by evaporation. As the construction of various reservoirs as a part of water resources developmental effort involve considerable inputs of money, which is a scarce resource, evaporation from such water bodies signifies an economic loss. In semi-arid zones where water is scarce, the importance of conservation of water through reduction of evaporation is obvious.

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Methods to Reduce Evaporation Losses Various methods available for reduction of evaporation losses can be considered in three categories: (i) Reduction of Surface Area Since the volume of water lost by evaporation is directly proportional to the surface area of the water body, the reduction of surface area wherever feasible reduces evaporation losses. Measures like having deep reservoirs in place of wider ones and elimination of shallow areas can be considered under this category. (ii) Mechanical Covers Permanent roofs over the reservoir, temporary roofs and floating roofs such as rafts and light-weight floating particles can be adopted wherever feasible. Obviously these measures are limited to very small water bodies such as ponds, etc. (iii) Chemical Films This method consists of applying a thin chemical film on the water surface to reduce evaporation. Currently this is the only feasible method available for reduction of evaporation of reservoirs up to moderate size. Certain chemicals such as cetyl alcohol (hexadecanol) and stearyl alcohol (octadecanol) form monomolecular layers on a water surface. These layers act as evaporation inhibitors by preventing the water molecules to escape past them. The thin film formed has the following desirable features: 1. The film is strong and flexible and does not break easily due to wave action. 2. If punctured due to the impact of raindrops or by birds, insects, etc., the film closes back soon after. 3. It is pervious to oxygen and carbon dioxide; the water quality is therefore not affected by its presence. 4. It is colourless, odourless and nontoxic. Cetyl alcohol is found to be the most suitable chemical for use as an evaporation inhibitor. It is a white, waxy, crystalline solid and is available as lumps, flakes or powder. It can be applied to the water surface in the form of powder, emulsion or solution in mineral turpentine. Roughly about 3.5 N/hectare/day of cetyl alcohol is needed for effective action. The chemical is periodically replenished to make up the losses due to oxidation, wind sweep of the layer to the shore and its removal by birds and insects. Evaporation reduction can be achieved to a maximum if a film pressure of 4 ´ 10–2 N/m is maintained. Controlled experiments with evaporation pans have indicated an evaporation reduction of about 60% through use of cetyl alcohol. Under field conditions, the reported values of evaporation reduction range from 20 to 50%. It appears that a reduction of 20–30% can be achieved easily in small size lakes (£1000 hectares) through the use of these monomolecular layers. The adverse effect of heavy wind appears to be the only major impediment affecting the efficiency of these chemical films.

B: EVAPOTRANSPIRATION 3.7 TRANSPIRATION Transpiration is the process by which water leaves the body of a living plant and reaches the atmosphere as water vapour. The water is taken up by the plant-root system

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and escapes through the leaves. The important factors affecting transpiration are: atmospheric vapour pressure, temperature, wind, light intensity and characteristics of the plant, such as the root and leaf systems. For a given plant, factors that affect the free-water evaporation also affect transpiration. However, a major difference exists between transpiration and evaporation. Transpiration is essentially confined to daylight hours and the rate of transpiration depends upon the growth periods of the plant. Evaporation, on the other hand, continues all through the day and night although the rates are different.

3.8

EVAPOTRANSPIRATION

While transpiration takes place, the land area in which plants stand also lose moisture by the evaporation of water from soil and water bodies. In hydrology and irrigation practice, it is found that evaporation and transpiration processes can be considered advantageously under one head as evapotranspiration. The term consumptive use is also used to denote this loss by evapotranspiration. For a given set of atmospheric conditions, evapotranspiration obviously depends on the availability of water. If sufficient moisture is always available to completely meet the needs of vegetation fully covering the area, the resulting evapotranspiration is called potential evapotranspiration (PET). Potential evapotranspiration no longer critically depends on the soil and plant factors but depends essentially on the climatic factors. The real evapotranspiration occurring in a specific situation is called actual evapotranspiration (AET). It is necessary to introduce at this stage two terms: field capacity and permanent wilting point. Field capacity is the maximum quantity of water that the soil can retain against the force of gravity. Any higher moisture input to a soil at field capacity simply drains away. Permanent wilting point is the moisture content of a soil at which the moisture is no longer available in sufficient quantity to sustain the plants. At this stage, even though the soil contains some moisture, it will be so held by the soil grains that the roots of the plants are not able to extract it in sufficient quantities to sustain the plants and consequently the plants wilt. The field capacity and permanent wilting point depend upon the soil characteristics. The difference between these two moisture contents is called available water, the moisture available for plant growth. If the water supply to the plant is adequate, soil moisture will be at the field capacity and AET will be equal to PET. If the water supply is less than PET, the soil dries out and the ratio AET/PET would then be less than unity. The decrease of the ratio AET/PET with available moisture depends upon the type of soil and rate of drying. Generally, for clayey soils, AET/PET = 1.0 for nearly 50% drop in the available moisture. As can be expected, when the soil moisture reaches the permanent wilting point, the AET reduces to zero (Fig. 3.5). For a catchment in a given period of time, the hydrologic budget can be written as (3.12) P – Rs – Go – Eact = DS where P = precipitation, Rs = surface runoff, Go = subsurface outflow, Eact = actual evapotranspiration (AET) and DS = change in the moisture storage. This water budgeting can be used to calculate Eact by knowing or estimating other elements of Eq. (3.12). Generally, the sum of Rs and Go can be taken as the stream flow at the basin outlet without much error. Method of estimating AET is given in Sec. 3.11.

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Fig. 3.5 Variation of AET Except in a few specialized studies, all applied studies in hydrology use PET (not AET) as a basic parameter in various estimations related to water utilizations connected with evapotranspiration process. It is generally agreed that PET is a good approximation for lake evaporation. As such, where pan evaporation data is not available, PET can be used to estimate lake evaporation.

3.9 MEASUREMENT OF EVAPOTRANSPIRATION The measurement of evapotranspiration for a given vegetation type can be carried out in two ways: either by using lysimeters or by the use of field plots.

Lysimeters A lysimeter is a special watertight tank containing a block of soil and set in a field of growing plants. The plants grown in the lysimeter are the same as in the surrounding field. Evapotranspiration is estimated in terms of the amount of water required to maintain constant moisture conditions within the tank measured either volumetric ally or gravimetrically through an arrangement made in the lysimeter. Lysimeters should be designed to accurately reproduce the soil conditions, moisture content, type and size of the vegetation of the surrounding area. They should be so buried that the soil is at the same level inside and outside the container. Lysimeter studies are time-consuming and expensive.

Field Plots In special plots all the elements of the water budget in a known interval of time are measured and the evapotranspiration determined as Evapotranspiration = [precipitation + irrigation input – runoff – increase in soil storage groundwater loss] Measurements are usually confined to precipitation, irrigation input, surface runoff and soil moisture. Groundwater loss due to deep percolation is difficult to measure and can be minimised by keeping the moisture condition of the plot at the field capacity. This method provides fairly reliable results.

3.10 EVAPOTRANSPIRATION EQUATIONS The lack of reliable field data and the difficulties of obtaining reliable evapotranspiration data have given rise to a number of methods to predict PET by using climatological

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71

data. Large number of formulae are available: they range from purely empirical ones to those backed by theoretical concepts. Two useful equations are given below.

Penman’s Equation Penman’s equation is based on sound theoretical reasoning and is obtained by a combination of the energy-balance and mass-transfer approach. Penman’s equation, incorporating some of the modifications suggested by other investigators is AH n + Ea g (3.13) PET = A+g where PET = daily potential evapotranspiration in mm per day A = slope of the saturation vapour pressure vs temperature curve at the mean air temperature, in mm of mercury per °C (Table 3.3) Hn = net radiation in mm of evaporable water per day Ea = parameter including wind velocity and saturation deficit g = psychrometric constant = 0.49 mm of mercury/°C The net radiation is the same as used in the energy budget [Eq. (3.8)] and is estimated by the following equation: n n Hn = Ha (1 – r) æ a + b ö – s Ta4 (0.56 - 0.092 ea ) æ 0.10 + 0.90 ö (3.14) è è Nø Nø where Ha = incident solar radiation outside the atmosphere on a horizontal surface, expressed in mm of evaporable water per day (it is a function of the latitude and period of the year as indicated in Table 3.4) a = a constant depending upon the latitude f and is given by a = 0.29 cos f b = a constant with an average value of 0.52 n = actual duration of bright sunshine in hours N = maximum possible hours of bright sunshine (it is a function of latitude as indicated in Table 3.5) r = reflection coefficient (albedo). Usual ranges of values of r are given below. Surface

Range of r values

Close ground corps Bare lands Water surface Snow

0.15–0.25 0.05–0.45 0.05 0.45–0.95

s = Stefan-Boltzman constant = 2.01 ´ 10–9 mm/day Ta = mean air temperature in degrees kelvin = 273 + °C ea = actual mean vapour pressure in the air in mm of mercury The parameter Ea is estimated as

in which

u2 ö æ Ea = 0.35 ç1 + (e - e ) è 160 ÷ø w a u2 = mean wind speed at 2 m above ground in km/day ew = saturation vapour pressure at mean air temperature in mm of mercury (Table 3.3) ea = actual vapour pressure, defined earlier

(3.15)

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For the computation of PET, data on n, ea, u2, mean air temperature and nature of surface (i.e. value of r) are needed. These can be obtained from actual observations or through available meteorological data of the region. Equations (3.13), (3.14) and (3.15) together with Tables 3.3, 3.4, and 3.5 enable the daily PET to be calculated. It may be noted that Penman’s equation can be used to calculate evaporation from a water surface by using r = 0.05. Penman’s equation is widely used in India, the UK, Australia and in some parts of USA. Further details about this equation are available elsewhere2,5,7. EXAMPLE 3.2 Calculate the potential evapotranspiration from an area near New Delhi in the month of November by Penman’s fomula. The following data are available: Latitude : 28°4¢ N Elevation : 230 m (above sea level) Table 3.3 Saturation Vapour Pressure of Water Temperature (°C)

Saturation vapour pressure ew (mm of Hg)

A (mm/°C)

0 5.0 7.5 10.0 12.5 15.0 17.5 20.0 22.5 25.0 27.5 30.0 32.5 35.0 37.5 40.0 45.0

4.58 6.54 7.78 9.21 10.87 12.79 15.00 17.54 20.44 23.76 27.54 31.82 36.68 42.81 48.36 55.32 71.20

0.30 0.45 0.54 0.60 0.71 0.80 0.95 1.05 1.24 1.40 1.61 1.85 2.07 2.35 2.62 2.95 3.66

æ 17.27 t ö mm of Hg, where t = temperature in °C. ew = 4.584 exp ç è 237.3 + t ÷ø

Table 3.4 Mean Monthly Solar Radiation at Top of Atmosphere, Ha in mm of Evaporable Water/Day North latitude Jan Feb Mar Apr May Jun

Jul

Aug

Sep

0° 10° 20° 30° 40° 50°

13.5 14.8 15.7 16.2 16.3 16.1

14.2 15.0 15.3 15.3 14.8 13.9

14.9 15.0 14.6 14.3 14.9 14.1 13.1 12.4 14.4 12.9 11.2 10.3 13.5 11.3 9.1 7.9 12.2 9.3 6.7 5.4 10.5 7.1 4.3 3.0

14.5 12.8 10.8 8.5 6.0 3.6

15.0 13.9 12.3 10.5 8.3 5.9

15.2 14.8 13.9 12.7 11.0 9.1

14.7 15.2 15.2 14.8 13.9 12.7

13.9 15.0 15.7 16.0 15.9 15.4

13.4 14.8 15.8 16.5 16.7 16.7

Oct Nov

Dec

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73

Table 3.5 Mean Monthly Values of Possible Sunshine Hours, N North latitude Jan

Feb Mar Apr May Jun

Jul

Aug

Sep

0° 10° 20° 30° 40° 50°

12.1 11.8 11.5 11.1 10.7 10.1

12.1 12.6 13.2 13.9 14.7 16.0

12.1 12.4 12.8 13.2 13.8 14.5

12.1 12.1 12.1 12.1 12.9 11.9 11.7 11.5 12.3 11.7 11.2 10.9 12.4 11.5 10.6 10.2 12.5 11.2 10.0 9.4 12.7 10.8 9.1 8.1

12.1 11.6 11.l 10.4 9.6 8.6

12.1 12.1 12.0 12.0 11.9 11.8

12.1 12.4 12.6 12.9 13.2 13.8

12.1 12.6 13.1 13.7 14.4 15.4

12.1 12.7 13.3 14.1 15.0 16.4

Mean monthly temperature Mean relative humidity Mean observed sunshine hours Wind velocity at 2 m height Nature of surface cover

SOLUTION: From Table 3.3, From Table 3.4 From Table 3.5

A = 1.00 mm/°C

: : : : :

Oct

Nov

Dec

19° C 75% 9h 85 km/day Close-ground green crop

ew = 16.50 mm of Hg

Ha = 9.506 mm of water/day

From given data

N = 10.716 h

ea a b s Ta s Ta4 r From Eq. (3.14), Hn

From Eq. (3.15),

n/N = 9/10.716 = 0.84

= 16.50 ´ 0.75 = 12.38 mm of Hg = 0.29 cos 28° 4¢ = 0.2559 = 0.52 = 2.01 ´ 10–9 mm/day = 273 + 19 = 292 K = 14.613 = albedo fer close-ground green crop is taken as 0.25 = 9.506 ´ (1 – 0.25) ´ (0.2559 + (0.52 ´ 0.84)) – 14.613 ´ (0.56 – 0.092 12.38 ) ´ (0.10 + (0.9 ´ 0.84)) = 4.936 – 2.946 = 1.990 mm of water/day

85 ö Ea = 0.35 ´ çæ1 + ´ (16.50 – 12.38) = 2.208 mm/day è 160 ÷ø From Eq. (3.13), noting the value of g = 0.49. (1 ´ 1.990) + (2.208 ´ 0.49) = 2.06 mm/day PET = (1.00 + 0.49)

EXAMPLE 3.3 Using the data of Example 3.2, estimate the daily evaporation from a lake situated in that place. SOLUTION: For estimating the daily evaporation from a lake, Penman’s equation is used with the albedo r = 0.05. Hence (1.0 - 0.05) Hn = 4.936 ´ – 2.946 = 6.252 – 2.946 = 3.306 mm of water/day (1.0 - 0.25) Ea = 2.208 mm/day

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From Eq. (3.13), PET = Lake evaporation (1.0 ´ 3.306) + (2.208 ´ 0.49) = = 2.95 mm/day (1.0 - 0.49)

Reference Crop Evapotranspiration (ETo ) In irrigation practice, the PET is extensively used in calculation of crop-water requirements. For purposes of standardization, FAO recommends3 a reference crop evapotranspiration or reference evapotranspiration denoted as ETo. The reference surface is a hypothetical grass reference crop with an assumed crop height of 0.12 m, a defined fixed surface resistance of 70 s m–1 and an albedo of 0.23. The reference surface closely resembles an extensive surface of green, well-watered grass of uniform height, actively growing and completely shading the ground. The defined fixed surface resistance 70 s m–1 implies a moderately dry soil surface resulting from about a weekly irrigation frequency. The FAO recommends a method called FAO Penman-Monteith method to estimate ETo by using radiation, air temperature, air humidity and wind speed data. Details of FAO Penman-Monteith method are available in Ref. 3. The potential evapotranspiration of any other crop (ET) is calculated by multiplying the reference crop evapotranspiration by a coefficient K, the value of which changes with stage of the crop. Thus ET = K(ETo) (3.16) The value of K varies from 0.5 to 1.3. Table 3.7 gives average values of K for some selected crops.

Empirical Formulae A large number of empirical formulae are available for estimation of PET based on climatological data. These are not universally applicable to all climatic areas. They should be used with caution in areas different from those for which they were derived. Blaney-Criddle Formula This purely empirical formula based on data from arid western United States. This formula assumes that the PET is related to hours of sunshine and temperature, which are taken as measures of solar radiation at an area. The potential evapotranspiration in a crop-growing season is given by ET = 2.54 KF and F = S Ph T f /100 (3.17) where ET = PET in a crop season in cm K = an empirical coefficient, depends on the type of the crop and stage of growth F = sum of monthly consumptive use factors for the period Ph = monthly percent of annual day-time hours, depends on the latitude of the place (Table 3.6) and T f = mean monthly temperature in °F Values of K depend on the month and locality. Average value for the season for selected crops is given in Table 3.7. The Blaney-Criddle formula is largely used by irrigation engineers to calculate the water requirements of crops, which is taken as the difference between PET and effective precipitation. Blaney-Morin equation is another empirical formula similar to Eq. (3.17) but with an additional correction for humidity.

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75

Table 3.6 Monthly Daytime Hours Percentages, Ph, for use in Blaney-Criddle Formula (Eq. 3.17) North latitude (deg) Jan Feb Mar Apr May Jun 0 10 15 20 25 30 35 40

8.50 8.13 7.94 7.74 7.53 7.30 7.05 6.76

7.66 7.47 7.36 7.25 7.14 7.03 6.88 6.72

8.49 8.45 8.43 8.41 8.39 8.38 8.35 8.33

8.21 8.37 8.44 8.52 8.61 8.72 8.83 8.95

8.50 8.81 8.98 9.15 9.33 9.53 9.76 10.02

8.22 8.60 8.80 9.00 9.23 9.49 9.77 10.08

Jul

Aug

Sep

Oct Nov Dec

8.50 8.86 9.05 9.25 9.45 9.67 9.93 10.22

8.49 8.71 8.83 8.96 9.09 9.22 9.37 9.54

8.21 8.25 8.28 8.30 8.32 8.33 8.36 8.39

8.50 8.34 8.26 8.18 8.09 7.99 7.87 7.75

8.22 7.91 7.75 7.58 7.40 7.19 6.97 6.72

8.50 8.10 7.88 7.66 7.42 7.15 6.86 6.52

Table 3.7 Values of K for Selected Crops Crop

Average value of K

Range of monthly values

Rice Wheat Maize Sugarcane Cotton Potatoes Natural Vegetation: (a) Very dense (b) Dense (c) Medium (d) Light

1.10 0.65 0.65 0.90 0.65 0.70

0.85–1.30 0.50–0.75 0.50–0.80 0.75–1.00 0.50–0.90 0.65–0.75

1.30 1.20 1.00 0.80

EXAMPLE 3.4 Estimate the PET of an area for the season November to February in which wheat is grown. The area is in North India at a latitude of 30° N with mean monthly temperatures as below: Month Temp. (°C)

Nov. 16.5

Dec. 13.0

Jan. 11.0

Feb. 14.5

Use the Blaney-Criddle formula.

SOLUTION: From Table 3.7, for wheat K = 0.65. Values of Ph for 30° N is read from Table 3.6, the temperatures are converted to Fahrenheit and the calculations are performed in the following table. Month Nov. Dec. Jan. Feb.

Tf

Ph

PhT f /100

61.7 55.4 51.8 58.1

7.19 7.15 7.30 7.03 S Ph T f /100 =

4.44 3.96 3.78 4.08 16.26

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By Eq. (3.17),

ET = 2.54 ´ 16.26 ´ 0.65 = 26.85 cm.

Thornthwaite Formula This formula was developed from data of eastern USA and uses only the mean monthly temperature together with an adjustment for day-lengths. The PET is given by this formula as a

where

æ 10 T ö (3.18) ET = 1.6 La ç è I t ÷ø ET = monthly PET in cm La = adjustment for the number of hours of daylight and days in the month, related to the latitude of the place (Table 3.8) T = mean monthly air temperature °C 12 It = the total of 12 monthly values of heat index = å i , 1 where i = ( T /5)1.514 a = an empirical constant = 6.75 ´ 10–7 I t3 – 7.71 ´ 10–5 It2 + 1.792 ´ 10–2It + 0.49239

Table 3.8 Adjustment Factor La for Use in Thornthwaite Formula (Eq. 3.18) North latitude (deg) Jan 0 10 15 20 25 30 40

1.04 1.00 0.97 0.95 0.93 0.90 0.84

Feb Mar Apr May Jun

Jul

Aug

Sep

Oct Nov Dec

0.94 0.91 0.91 0.90 0.89 0.87 0.83

1.04 1.08 1.12 1.14 1.17 1.20 1.27

1.04 1.07 1.08 1.11 1.12 1.14 1.18

1.01 1.02 1.02 1.02 1.02 1.03 1.04

1.04 1.02 1.01 1.00 0.99 0.98 0.96

1.04 1.03 1.03 1.03 1.03 1.03 1.03

1.01 1.03 1.04 1.05 1.06 1.08 1.11

1.04 1.08 1.11 1.13 1.15 1.18 1.24

1.01 1.06 1.08 1.11 1.14 1.17 1.25

1.01 0.98 0.95 0.93 0.91 0.89 0.83

1.04 0.99 0.97 0.94 0.91 0.88 0.81

3.11 POTENTIAL EVAPOTRANSPIRATION OVER INDIA Using Penman’s equation and the available climatological data, PET estimate5 for the country has been made. The mean annual PET (in cm) over various parts of the country is shown in the form of isopleths—the lines on a map through places having equal depths of evapotranspiration [Fig. 3.6(a)]. It is seen that the annual PET ranges from 140 to 180 cm over most parts of the country. The annual PET is highest at Rajkot, Gujarat with a value of 214.5 cm. Extreme south-east of Tamil Nadu also show high average values greater than 180 cm. The highest PET for southern peninsula is at Tiruchirapalli, Tamil Nadu with a value of 209 cm. The variation of monthly PET at some stations located in different climatic zones in the country is shown in Fig. 3.6(b). Valuable PET data relevant to various parts of the country are available in Refs 4 and 7.

3.12 ACTUAL EVAPOTRANSPIRATION (AET) AET for hydrological and irrigation applications can be obtained through a process water budgeting and accounting for soil-plant-atmosphere interactions. A simple procedure due to Doorenbos and Pruit is as follows:

Abstractions from Precipitation

Fig. 3.6(a)

77

Annual PET (cm) over India (Source: Scientific: Report No. 136, IMD, 1971, © Government of India Copyright)

Based upon survey of India map with the permission of the Surveyor General of India, © Government of India Copyright 1984 The territorial waters of India extend into the sea to a distance of 200 nautical miles measured from the appropriate baseline Responsibility for the correctness of internal details on the map rests with the publisher.

Fig. 3.6(b) Monthly Variation of PET (mm) (Source: Scientific Report No. 136, India Meteorological Department, 1971, © Government of India Copyright)

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1. Using available meteorological data the reference crop evapotranspiration (ETo) is calculated. 2. The crop coefficient K for the given crop (and stage of growth) is obtained from published tables such as Table 3.7. The potential crop evapotrans-piration ETc is calculated using Eq. 3.16 as ETc = K(ETo). 3. The actual evapotranspiration (ETa) at any time t at the farm having the given crop is calculated as below: l If AASW ³ (1 – p) MASW ETa = ETo (known as potential condition) (3.19-a) l If AASW < (1 – p) MASW AASW ù ET ETa = éê (3.19-b) ú c p MASW (1 ) ë û where MASW = total available soil water over the root depth AASW = actual available soil-water at time t over the root depth p = soil-water depletion factor for a given crop and soil complex. (Values of p ranges from about 0.1 for sandy soils to about 0.5 for clayey soils)

[Note the equivalence of terms used earlier as PET = ETo and AET = ETa]

EXAMPLE 3.5 A recently irrigated field plot has on Day 1 the total available soil moisture at its maximum value of 10 cm. If the reference crop evapotranspiration is 5.0 mm/ day, calculate the actual evapotranspiration on Day 1, Day 6 and Day 7. Assume soilwater depletion factor p = 0.20 and crop factor K = 0.8. SOLUTION: Here ETo = 5.0 mm and MASW = 100 mm

(1– p) MASW = (1 – 0.2) ´ 100 = 80.0 and ETc = 0.9 ´ 5.0 = 4.5 mm/day AASW = 100 mm > (1 – p) MASW Hence potential condition exists and ETa = ETc = 4.5 mm/day This rate will continue till a depletion of (100 – 80) = 20 mm takes place in the soil. This will take 20/4.5 = 4.44 days. Thus Day 5 also will have ETa = ETc = 4.5 mm/day Day 6: At the beginning of Day 6, AASW = (100 – 4.5 ´ 5) = 77.5 mm Since AASW < (1 – p) MASW, Day 1:

Day 7:

77.5 ù ETa = éê ´ 4.5 = 4.36 mm ë 80.0 úû At the beginning of Day 7, AASW = (77.5 – 4.36) = 73.14 mm Since AASW < (1 – p) MASW 73.14 ù ETa = éê ´ 4.5 = 4.11 mm. ë 80.0 úû AASW at the end of Day 7 = 73.14 – 4.11 = 69.03 mm.

C: INITIAL LOSS In the precipitation reaching the surface of a catchment the major abstraction is from the infiltration process. However, two other processes, though small in magnitude, operate to reduce the water volume available for runoff and thus act as abstractions. These are (i) the interception process, and (ii) the depression storage and together they are called the initial loss. This abstraction represents the quantity of storage that must be satisfied before overland runoff begins. The following two sections deal with these two processes briefly.

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79

3.13 INTERCEPTION When it rains over a catchment, not all the precipitation falls directly onto the ground. Before it reaches the ground, a part of it may be caught by the vegetation and subsequently evaporated. The volume of water so caught is called interception. The intercepted precipitation may follow one of the three possible routes: 1. It may be retained by the vegetation as surface storage and returned to the atmosphere by evaporation; a process termed interception loss; 2. It can drip off the plant leaves to join the ground surface or the surface flow; this is known as throughfall; and 3. The rainwater may run along the leaves and branches and down the stem to reach the ground surface. This part is called stemflow. Interception loss is solely due to evaporation and does not include transpiration, throughfall or stemflow. The amount of water intercepted in a given area is extremely difficult to measure. It depends on the species composition of vegetation, its density and also on the storm characteristics. It is estimated that of the total rainfall in an area during a plant-growing season the interception loss is about 10 to 20%. Interception is satisfied during the first part of a storm and if an area Fig. 3.7 Typical Interception Loss Curve experiences a large number of small storms, the annual interception loss due to forests in such cases will be high, amounting to greater than 25% of the annual precipitation. Quantitatively, the variation of interception loss with the rainfall magnitude per storm for small storms is as shown in Fig. 3.7. It is seen that the interception loss is large for a small rainfall and levels off to a constant value for larger storms. For a given storm, the interception loss is estimated as Ii = Si + KiEt (3.18) where Ii = interception loss in mm, Si = interception storage whose value varies from 0.25 to 1.25 mm depending on the nature of vegetation, Ki = ratio of vegetal surface area to its projected area, E = evaporation rate in mm/h during the precipitation and t = duration of rainfall in hours. It is found that coniferous trees have more interception loss than deciduous ones. Also, dense grasses have nearly same interception losses as full-grown trees and can account for nearly 20% of the total rainfall in the season. Agricultural crops in their growing season also contribute high interception losses. In view of these the interception process has a very significant impact on the ecology of the area related to silvicultural aspects, in in situ water harvesting and in the water balance of a region. However, in hydrological studies dealing with floods interception loss is rarely significant and is not separately considered. The common practice is to allow a lump sum value as the initial loss to be deducted from the initial period of the storm.

3.14 DEPRESSION STORAGE When the precipitation of a storm reaches the ground, it must first fill up all depressions

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before it can flow over the surface. The volume of water trapped in these depressions is called depression storage. This amount is eventually lost to runoff through processes of infiltration and evaporation and thus form a part of the initial loss. Depression storage depends on a vast number of factors the chief of which are: (i) the type of soil, (ii) the condition of the surface reflecting the amount and nature of depression, (iii) the slope of the catchment, and (iv) the antecedent precipitation, as a measure of the soil moisture. Obviously, general expressions for quantitative estimation of this loss are not available. Qualitatively, it has been found that antecedent precipitation has a very pronounced effect on decreasing the loss to runoff in a storm due to depression. Values of 0.50 cm in sand, 0.4 cm in loam and 0.25 cm in clay can be taken as representatives for depression-storage loss during intensive storms.

D: INFILTRATION 3.15 INFILTRATION Infiltration is the flow of water into the ground through the soil surface. The distribution of soil moisture within the soil profile during the infiltration process is illustrated in Fig. 3.8. When water is applied at the surface of a soil, four moisture zones in the soil, as indicated in Fig. 3.8 can be identified. Zone 1: At the top, a thin layer of saturated zone is created. Zone 2: Beneath zone 1, there is a transition zone. Zone 3: Next lower zone is the trans-mission zone where the downward motion of the moisture takes place. The moisture content in this zone Fig. 3.8 Distribution of Soil Moisture in the Infiltrais above field capacity but below tion Process saturation. Further, it is characterized by unsaturated flow and fairly uniform moisture content. Zone 4: The last zone is the wetting zone. The soil moisture in this zone will be at or near field capacity and the moisture content decreases with the depth. The boundary of the wetting zone is the wetting front where a sharp discontinuity exists between the newly wet soil and original moisture content of the soil. Depending upon the amount of infiltration and physical properties of the soil, the wetting front can extend from a few centimetres to metres. The infiltration process can be easily understood through a simple analogy. Consider a small container Fig. 3.9 An Analogy for covered with wire gauze as in Fig. 3.9. If water is Infiltration

Abstractions from Precipitation

81

poured into the container a part of it will go into the container and a part overflows. Further, the container can hold only a fixed quantity and when it is full no more flow into the container can take place. While this analogy is highly simplified, it underscores two important aspects; viz. (i) the maximum rate at which the ground can absorb water, the infiltration capacity and (ii) the volume of water that the ground can hold, the field capacity. Since the infiltered water may contribute to the ground water discharge in addition to increasing the soil moisture, the process can be schematically modelled as in Fig. 3.10(a) and (b) wherein two situations, viz. low intensity rainfall and high intensity rainfall are considered.

Fig. 3.10 An Infiltration Model

3.16 INFILTRATION CAPACITY The maximum rate at which a given soil at a given time can absorb water is defined as the infiltration capacity. It is designated as fp and is expressed in units of cm/h. The actual rate of infiltration f can be expressed as f = fp when i ³ fp and f = i when i < fp (3.20) where i = intensity of rainfall. The infiltration capacity of a soil is high at the beginning of a storm and has an exponential decay as the time elapses. The typical variation of the infiltration capacity fp of a soil with time is shown in Fig. 3.11. The infiltration capacity of an area is dependent on a large number of factors, chief of them are:

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Characteristics of the soil (Texture, porosity and hydraulic conductivity) Condition of the soil surface l Current moisture content l Vegetative cover and l Soil temperature A few important factors affecting fp are described below: l l

Characteristics of Soil The type of soil, viz. sand, silt or clay, its texture, structure, permeability and underdrainage are the important characteristics under this category. A loose, permeable, sandy soil will have a larger infiltration capacity than a tight, clayey soil. A soil with good underdrainage, i.e. the facility to transmit the infiltered water downward to a groundwater storage would obviously have a higher infiltration capacity. When the soils occur in layers, the transmission capacity of the layers determines the overall infiltration rate. Also, a dry soil can absorb more water than Fig. 3.11 Variation of Infiltration Capacity one whose pores are already full (Fig. 3.11). The land use has a significant influence on fp. For example, a forest soil rich in organic matter will have a much higher value of fp under identical conditions than the same soil in an urban area where it is subjected to compaction. Surface of Entry At the soil surface, the impact of raindrops causes the fines in the soil to be displaced and these in turn can clog the pore spaces in the upper layers of the soil. This is an important factor affecting the infiltration capacity. Thus a surface covered with grass and other vegetation which can reduce this process has a pronounced influence on the value of fp. Fluid Characteristics Water infiltrating into the soil will have many impurities, both in solution and in suspension. The turbidity of the water, especially the clay and colloid content is an important factor and such suspended particles block the fine pores in the soil and reduce its infiltration capacity. The temperature of the water is a factor in the sense that it affects the viscosity of the water by which in turn affects the infiltration rate. Contamination of the water by dissolved salts can affect the soil structure and in turn affect the infiltration rate.

3.17 MEASUREMENT OF INFILTRATION Infiltration characteristics of a soil at a given location can be estimated by l Using flooding type infiltrometers l Measurement of subsidence of free water in a large basin or pond l Rainfall simulator l Hydrograph analysis

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83

Flooding-Type Infiltrometer Flooding-type infiltrometers are experimental devices used to obtain data relating to variation of infiltration capacity with time. Two types of flooding type infiltrometers are in common use. They are (a) Tube-type (or Simple) infiltrometer and (b) Doublering infiltrometer. Simple (Tube Type) Infiltrometer This is a simple instrument consisting essentially of a metal cylinder, 30 cm diameter and 60 cm long, open at both ends. The cylinder is driven into the ground to a depth of 50 cm (Fig. 3.12(a)). Water is poured into the top part to a depth of 5 cm and a pointer is set to mark the water level. As infiltration proceeds, the volume is made up by adding water from a burette to keep the water level at the tip of the pointer. Knowing the volume of water added during different time intervals, the plot of the infiltration capacity vs time is obtained. The experiments are continued till a uniform rate of infiltration is obtained and this may take 2–3 hours. The surface of the soil is usually protected by a perforated disc to prevent formation of turbidity and its settling on the soil surface.

Fig. 3.12 Flooding Type Infiltrometers A major objection to the simple infiltrometer as above is that the infiltered water spreads at the outlet from the tube (as shown by dotted lines in Fig. 3.12(a)) and as such the tube area is not representative of the area in which infiltration is taking place. Double-ring Infiltrometer This most commonly used infiltrometer is designed to overcome the basic objection of the tube infiltrometer, viz. the tube area is not representative of the infiltrating area. In this, two sets of concentrating rings with diameters of 30 cm and 60 cm and of a minimum length of 25 cm, as shown in Fig. 3.12(b), are used. The two rings are inserted into the ground and water is applied into both the rings to maintain a constant depth of about 5.0 cm. The outer ring provides water jacket to the infiltering water from the inner ring and hence prevents the spreading out of the infiltering water of the inner ring. The water depths in the inner and outer rings are kept the same during the observation period. The measurement of

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the water volume is done on the inner ring only. The experiment is carried out till a constant infiltration rate is obtained. A perforated disc to prevent formation of turbidity and settling of fines on the soil surface is provided on the surface of the soil in the inner ring as well as in the annular space. As the flooding-type infiltrometer measures the infiltration characteristics at a spot only, a large number of pre-planned experiments are necessary to obtain representative infiltration characteristics for an entire watershed. Some of the chief disadvantages of flooding-type infiltrometers are: 1. the raindrop impact effect is not simulated; 2. the driving of the tube or rings disturbs the soil structure; and 3. the results of the infiltrometers depend to some extent on their size with the larger meters giving less rates than the smaller ones; this is due to the border effect.

Rainfall Simulator In this a small plot of land, of about 2 m ´ 4 m size, is provided with a series of nozzles on the longer side with arrangements to collect and measure the surface runoff rate. The specially designed nozzles produce raindrops falling from a height of 2 m and are capable of producing various intensities of rainfall. Experiments are conducted under controlled conditions with various combinations of intensities and durations and the surface runoff rates and volumes are measured in each case. Using the water budget equation involving the volume of rainfall, infiltration and runoff, the infiltration rate and its variation with time are estimated. If the rainfall intensity is higher than the infiltration rate, infiltration capacity values are obtained. Rainfall simulator type infiltrometers give lower values than flooding type infiltrometers. This is due to effect of the rainfall impact and turbidity of the surface water present in the former.

Hydrograph Analysis Reasonable estimation of the infiltration capacity of a small watershed can be obtained by analyzing measured runoff hydrographs and corresponding rainfall records. If sufficiently good rainfall records and runoff hydrographs corresponding to isolated storms in a small watershed with fairly homogeneous soils are available, water budget equation can be applied to estimate the abstraction by infiltration. In this the evapotranspiration losses are estimated by knowing the land cover/use of the watershed.

3.18 M O D E L I N G INFILTRATION CAPACITY Figure 3.13 shows a typical variation of infiltration capacity f p with time.

Fig. 3.13 Curves of Infiltration Capacity and Cumulative Infiltration Capacity

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85

Cumulative infiltration capacity Fp(t) is defined as the accumulation of infiltration volume over a time period since the start of the process and is given by Fp =

t

ò f p ( t ) dt

(3.21-a)

Thus the curve Fp(t) vs time in Fig. (3.13) is the mass curve of infiltration. It may be noted that from Eq. (3.21-a) it follow that dFp ( t ) (3.21-b) fp(t) = dt Many equations have been proposed to express the curves fp(t) or Fp(t) for use in hydrological analysis. In this section four such equations will be described.

[Note: Practically all the infiltration equations relate infiltration capacity fp(t) or cumulative infiltration capacity Fp(t) with time and other parameters. As such many authors find it convenient to drop the suffix p while denoting capacity. Thus fp is denoted as f and Fp as F.]

Horton’s Equation (1933) Horton expressed the decay of infiltration capacity with time as an exponential decay given by -K t fp = fc + (f0 – fc) e h for 0 ³ t £ tc (3.22) where fp = infiltration capacity at any time t from the start of the rainfall f0 = initial infiltration capacity at t = 0 fc = final steady state infiltration capacity occurring at t = tc. Also, fc is sometimes known as constant rate or ultimate infiltration capacity. Kh = Horton’s decay coefficient which depends upon soil characteristics and vegetation cover. The difficulty of determining the variation of the three parameters f0, fc and kh with soil characteristics and antecedent moisture conditions preclude the general use of Eq. (3.22). Philip’s Equation (1957) Philip’s two term model relates Fp(t) as

Fp = st1/2 + Kt where s = a function of soil suction potential and called as sorptivity K = Darcy’s hydraulic conductivity By Eq. (3.21-b) infiltration capacity could be expressed as 1 fp = st -1/ 2 + K 2

(3.23)

(3.24)

Kostiakov Equation (1932) Kostiakov model expresses cumulative infiltration capacity as Fp = atb (3.25) where a and b are local parameters with a > 0 and 0 < b < 1. The infiltration capacity would now b e expressed by Eq. (3.21-b) as fp = (ab) t(b–1) (3.26) Green–Ampt Equation (1911) Green and Ampt proposed a model for infiltration capacity based on Darcy’s law as

æ hSc ö fp = K ç 1 + Fp ÷ø è

(3.27)

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where

h = porosity of the soil Sc = capillary suction at the wetting front and K = Darcy’s hydraulic conductivity. Eq. (3.27) could be considered as n fp = m + Fp where m and n are Green–Ampt parameters of infiltration model.

(3.28)

Estimation of Parameters of Infiltration Models Data from infiltrometer experiments can be processed to generate data sets fp and Fp values for various time t values. The following procedures are convenient to evaluate the parameters of the infiltration models. Horton’s Model Value of fc in a test is obtained from inspection of the data. Equation (3.22) is rearranged to read as -K t (fp – fc) = (f0 – fc) e h (3.22-a) Taking logarithms ln(fp – fc) = ln(fo – fc) – Kht Plot ln(fp – fc) against t and fit the best straight line through the plotted points. The intercept gives ln(f0 – fc) and the slope of the straight line is Kh. Philip’s Model Use the expression for fp as 1 fp = st -1/ 2 + K (3.24) 2 Plot the observed values of fp against t – 0.5 on an arithmetic graph paper. The best fitting straight line through the plotted points gives K as the intercept and (s/2) as the slope of the line. While fitting Philip’s model it is necessary to note that K is positive and to achieve this it may be necessary to neglect a few data points at the initial stages (viz. at small values of t) of the infiltration experiment. K will be of the order of magnitude of the asymptotic value of fp. Kostiakov Model Kostiakov model relates Fp to t as Fp = atb (3.25) Taking logarithms of both sides of Eq. (3.25), ln(Fp) = ln a + b ln(t) The data is plotted as ln(Fp) vs ln(t) on an arithmetic graph paper and the best fit straight through the plotted points gives ln a as intercept and the slope is b. Note that b is a positive quantity such that 0 < b < 1. Green–Ampt Model Green–Ampt equation is considered in the form fp = m + n . Values of fp are plotted against (1/Fp) on a simple arithmetic graph paper and the Fp

best fit straight line is drawn through the plotted points. The intercept and the slope of the line are the coefficients m and n respectively. Sometimes values of fp and corresponding Fp at very low values of t may have to be omitted to get best fitting straight line with reasonably good correlation coefficient.

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87

[Note: 1. Procedure for calculation of the best fit straight line relating the dependent variable Y and independent variable X by the least-square error method is described in Section 4.9, Chapter 4. 2. Use of spread sheets (for eg., MS Excel) greatly simplifies these procedures and the best values of parameters can be obtained by fitting regression equations. Further, various plots and the coefficient of correlation, etc. can be calculated with ease.]

EXAMPLE 3.6 Infiltration capacity data obtained in a flooding type infiltration test is

given below:

Time since start 5 (minutes) Cumulative 1.75 infiltration depth (cm)

10

15

25

45

60

3.00

3.95

5.50

7.25

8.30

75

90

110

130

9.30 10.20 11.28 12.36

(a) For this data plot the curves of (i) infiltration capacity vs time, (ii) infiltration capacity vs cumulative infiltration, and (iii) cumulative infiltration vs time. (b) Obtain the best values of the parameters in Horton’s infiltration capacity equation to represent this data set.

SOLUTION: Incremental infiltration values and corresponding infiltration intensities fp at various data observation times are calculated as shown in the following Table. Also other data required for various plots are calculated as shown in Table 3.9.

Table 3.9 Calculations for Example 3.6

Time in Minutes

Cum. Depth (cm)

Incremental Depth in the interval (cm)

Infiltration rate, fp(cm/h)

0 5 10 15 25 45. 60 75 90 110 130

1.75 3.00 3.95 5.50 7.25 8.30 9.30 10.20 11.28 12.36

1.75 1.25 0.95 1.55 1.75 1.05 1.00 0.90 1.08 1.08

21.00 15.00 11.40 9.30 5.25 4.20 4.00 3.60 3.24 3.24

Ln(fp – fc) 2.877 2.465 2.099 1.802 0.698 –0.041 –0.274 –1.022

Time in hours 0.083 0.167 0.250 0.417 0.750 1.000 1.250 1.500 1.833 2.167

(a) Plots of fp vs time and Fp vs time are shown in Fig. 3.14. Best fitting curve for plotted points are also shown in the Fig. 3.14-a. Plot of fp vs Fp is shown in Fig. 3.14-b. (b) By observation from Table 3.9, fc = 3.24 cm/h Ln(fp – fc) is plotted against time t as shown in Fig. 3.14-c. The best fit line through the plotted points is drawn and its equation is obtained as

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Fig. 3.14 (a) Plot of Fp vs Time and fp vs Time

Fig. 3.14 (b) Plot of fp vs Fp

Fig. 3.14 (c) Horton’s Equation. Plot of ln(fp – fc) vs Time

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ln(fp – fc) = 2.8868 – 2.6751 t –Kh = slope of the best fit line = –2.6751, thus Kh = 2.6751 h–1 ln(f0 – fc) = intercept = 2.8868, thus f0 – fc = 17.94 and f0 = 21.18 cm/h

EXAMPLE 3.7 Values of infiltration capacities at various times obtained from an infiltration test are given below. Determine the parameters of (i) Green–Ampt equation, (ii) Philip’s equation, and (iii) Kostiakov’s equation that best fits this data. Time since start (minutes) 5 Cumulative infiltration depth (cm) 1.0

10

15

20

25

30

60

90

120

150

1.8

2.5

3.1

3.6

4.0

6.1

8.1

9.9

11.6

SOLUTION: Incremental infiltration depth values and corresponding infiltration intensities

fp at various data observation times are calculated as shown in Table 3.10. Also, various parameters needed for plotting different infiltration models are calculated as shown in Table 3.10. The units used are fp in cm/h, Fp in cm and t in hours.

Table 3.10 Calculations Relating to Example 3.7 1

2

Time (min)

Fp (cm)

5 10 15 20 25 30 60 90 120 150

1.0 1.8 2.5 3.1 3.6 4.0 6.1 8.1 9.9 11.6

3 4 Incremental depth of infiltration fp (cm) (cm/h) 1.0 0.8 0.7 0.6 0.5 0.4 2.1 2.0 1.8 1.7

Green–Ampt Equation: Values of fp (col. 4) are plotted against 1/Fp (col. 7) on an arithmetic graph paper (Fig. 3.15-a). The best fit straight line through the plotted points is obtained as 1 ö fp = 10.042 æ çè Fp ÷ø + 3.0256.

5

6

7

8

9

t in hours

t –0.5

1/Fp

Ln Fp

Ln t

12.0 9.6 8.4 7.2 6.0 4.8 4.2 4.0 3.6 3.4

0.083 0.167 0.250 0.333 0.417 0.500 1.000 1.500 2.000 2.500

3.464 2.449 2.000 1.732 1.549 1.414 1.000 0.816 0.707 0.632

1.000 0.556 0.400 0.323 0.278 0.250 0.164 0.123 0.101 0.086

0.000 0.588 0.916 1.131 1.281 1.386 1.808 2.092 2.293 2.451

–2.485 –1.792 –1.386 –1.099 –0.875 –0.693 0.000 0.405 0.693 0.916

fp = m +

n Fp

(3.28)

Fig. 3.15 (a) Fitting of Green–Ampt Equation

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The coefficients of the Green– Ampt equations are m = 3.0256 and n = 10.042 Philip’s Equation: The ex1 pression fp(t) = st -1/ 2 +K 2 (Eq. 3.24) is used. Values of fp (Col. 4) are plotted against t–0.5 (col. 6) on an arithmetic graph paper (Fig. 15-b). The best fit straight line through the plotted points is obtained as fp = 3.2287 t–0.5 + 1.23 The coefficients of Philip’s equation are s = 2 ´ 3.2287 = Fig. 3.15 (b) Fitting of Philip’s Equation 6.4574 and K = 1.23 Kostiakov’s Equation: Fp(t) = atb Eq. (3.25) Taking logarithms of both sides of the equation (3.25) ln(Fp) = ln a + b ln(t). The data set is plotted as ln(Fp) vs ln(t) on an arithmetic graph paper (Fig. 3.15-c) and the best Fig. 3.15 (c) Fitting of Kostiakov Equation fit straight line through the plotted points is obtained as ln(Fp) = 1.8346 + 0.6966 in(t). The coefficients of Kostiakov equation are b = 0.6966 and ln a = 1.8346 and hence a = 6.2626. Best fitting Kostiakov equation for the data is Fp = 6.2626 t0.6966 EXAMPLE 3.8 The infiltration capacity in a basin is represented by Horton’s equation as

fp = 3.0 + e–2t where fp is in cm/h and t is in hours. Assuming the infiltration to take place at capacity rates in a storm of 60 minutes duration, estimate the depth of infiltration in (i) the first 30 minutes and (ii) the second 30 minutes of the storm.

SOLUTION: t

Fp =

òf 0

p

dt

and fp = 3.0 + e–2t

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91

(i) In the first 0.5 hour 0.5

Fp1 =

ò 0

0.5

1 (3.0 + e -2 t ) dt = éê 3.0 t - e -2 t ùú 2 ë û0

= [(3.0 ´ 0.5) – (1/2)(e–(2 ´ 0.5)] – [–(1/2)] = (1.5 – 0.184) + 0.5 = 1.816 cm (ii) In the second 0.5 hour 1.0

Fp2 =

ò

0.50

1.0

1 (3.0 + e -2 t ) dt = éê 3.0 t - e -2 t ùú 2 ë û 0.5

= [(3.0 ´ 1.0) – (1/2)(e–2)] – [(3.0 ´ 0.5) – (l/2)(e–(2 ´ 0.5))] = (3.0 – 0.0677) – (1.5 – 0.184) = 1.616 cm

EXAMPLE 3.9 The infiltration capacity of soil in a small watershed was found to be 6 cm/h before a rainfall event. It was found to be 1.2 cm/h at the end of 8 hours of storm. If the total infiltration during the 8 hours period of storm was 15 cm, estimate the value of the decay coefficient Kh in Horton’s infiltration capacity equation. SOLUTION: Horton’s equation is fp = fc + (f0 – fc) e t

and

Fp = ¥

òf

- Kh t

t

p (t )

ò

dt = f c t + ( f 0 - f c ) e - K h t dt

1 As t ® ¥, e - K h t dt ® . Hence for large t values Kh 0 ( f0 - fc ) Fp = fct + Kh Here Fp = 15.0 cm, f0 = 6.0 cm, fc = 1.2 cm and t = 8 hours. 15.0 = (1.2 ´ 8) + (6.0 – 1.2)/Kh Kh = 4.8/5.4 = 0.888 h–1

ò

3.19 CLASSIFICATION OF INFILTRATION CAPACITIES For purposes of runoff volume classification in small watersheds, one of the widely used methods is the SCS–CN method described in detail in Chapter 5. In this method, the soils are considered divided into four groups known as hydrologic soil groups. The steady state infiltration capacity, being one of the main parameters in this soil classification, is divided into four infiltration classes as mentioned below. Table 3.11 Classification of Infiltration Capacities Infiltration Class

Infiltration Capacity (mm/h)

Very Low Low

< 2.5 2.5 to 25.0

Medium High

12.5 to 25.0 >25.0

Remarks Highly clayey soils Shallow soils, Clay soils, Soils low in organic matter Sandy loam, Silt Deep sands, well drained aggregated soils

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3.20 INFILTRATION INDICES In hydrological calculations involving floods it is found convenient to use a constant value of infiltration rate for the duration of the storm. The defined average infiltration rate is called infiltration index and two types of indices are in common use.

j–Index The j-index is the average rainfall above which the rainfall volume is equal to the runoff volume. The jindex is derived from the rainfall hyetograph with the knowledge of the resulting runoff volume. The initial loss is also considered as infiltration. The j value is found by treating it as a constant infiltration capacity. If the rainfall intensity is less than j, then the infiltration rate is equal to the rainFig. 3.16 j-Index fall intensity; however, if the rainfall intensity is larger than j the difference between the rainfall and infiltration in an interval of time represents the runoff volume as shown in Fig. 3.16. The amount of rainfall in excess of the index is called rainfall excess. In connection with runoff and flood studies it is also known as effective rainfall, (details in Sec. 6.5, Chapter 6). The j– index thus accounts for the total abstraction and enables magnitudes to be estimated for a given rainfall hyetograph. A detailed procedure for calculating j–index for a given storm hyetograph and resulting runoff volume is as follows. Procedure for Calculation of j-index Consider a rainfall hyetograph of event duration D hours and having N pulses of time interval Dt such that N × Dt = D. (In Fig. 3.16, N = 7) Let Ii be the intensity of rainfall in ith pulse and Rd = total direct runoff. Total Rainfall P =

N

å I i × Dt 1

If j is j-index, then P – j × te = Rd where te = duration of rainfall excess. If the rainfall hyetograph and total runoff depth Rd are given, the j-index of the storm can be determined by trial and error procedure as given below. 1. Assume that out of given N pulses, M number of pulses have rainfall excess. (Note that M £ N). Select M number of pulses in decreasing order of rainfall intensity Ii. 2. Find the value of j that satisfies the relation Rd =

M

å ( I i - j ) Dt 1

3. Using the value of j of Step 2, find the number of pulses (Mc) which give rainfall excess. (Thus Mc = number of pulses with rainfall intensity Ii ³ j). 4. If Mc = M, then j of Step 2 is the correct value of j-index. If not, repeat the procedure Step 1 onwards with new value of M. Result of Step 3 can be used as guidance to the next trial.

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93

Example 3.10 illustrates this procedure in detail. EXAMPLE 3.10 A storm with 10 cm of precipitation produced a direct runoff of 5.8 cm. The duration of the rainfall was 16 hours and its time distribution is given below. Estimate the j-index of the storm. Time from start (h) Cumulative rainfall (cm)

0 0

2 0.4

4 1.3

6 2.8

8 5.1

10 6.9

12 8.5

14 9.5

16 10.0

SOLUTION: Pulses of uniform time duration Dt = 2 h are considered. The pulses are

numbered sequentially and intensity of rainfall in each pulse is calculated as shown below.

Table 3.12 Calculations for Example 3.10 Pulse number

1

Time from start of rain (h) 2 Cumulative rainfall (cm) 0.4 Incremental rain (cm) 0.40 Intensity of rain (Ii) in cm/h. 0.20

2

3

4

5

6

7

8

4 1.3 0.90

6 2.8 1.50

8 5.1 2.30

10 6.9 1.80

12 8.5 1.60

14 9.5 1.00

16 10.0 0.50

0.45

0.75

1.15

0.90

0.80

0.50

0.25

Here duration of rainfall D = 16 h, Dt = 2 h and N = 8. Trial 1:

Assume M = 8, Dt = 2 h and hence te = M × Dt = 16 hours. Since M = N, all the pulses are included. Runoff Rd = 5.8 cm =

8

8

1

1

å (Ii – j)Dt = å Ii × Dt – j (8 ´ 2)

5.8 = {(0.20 ´ 2) + (0.45 ´ 2) + (0.75 ´ 2) + (1.15 ´ 2) + (0.90 ´ 2) + (0.80 ´ 2) + (0.50 ´ 2) + (0.25 ´ 2)} – 16 j = 10.0 – 14 j j = 4.2/14 = 0.263 cm/h

Fig. 3.17 Hyetograph and Rainfall Excess of the Storm – Example 3.10

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Engineering Hydrology

By inspection of row 5 of Table 3.12, Mc = number of pulses having Ii ³ j, that is Ii ³ 0.263 cm/h is 6. Thus Mc = 6 ¹ M. Hence assumed M is not correct. Try a new value of M < 8 in the next trial. Trial 2: Assume M = 7, Dt = 2 h and hence te = M × Dt = 14 hours. Select these 7 pulses in decreasing order of Ii. Pulse 1 is omitted. Runoff Rd = 5.8 cm =

7

7

1

1

å(Ii – j) Dt = å(Ii × Dt – j (7 ´ 2)

5.8 = {(0.45 ´ 2) + (0.75 ´ 2) + (1.15 ´ 2) + (0.90 ´ 2) + (0.80 ´ 2) + (0.50 ´ 2) + (0.25 ´ 2)} – 14 j = 9.6 – 14 j j = 3.8/14 = 0.271 cm/h By inspection of row 5 of Table 3.12, Mc = number of pulses having Ii ³ j, that is Ii ³ 0.271 cm/h is 6. Thus Mc = 6 ¹ M. Hence assumed M is not O.K. Try a new value of M < 7 in the next trial. Trial 3: Assume M = 6 × Dt = 2 h and hence te = M × Dt = 12 hours. Select these 6 pulses in decreasing order of Ii. Pulse 1 and 8 are omitted. Runoff Rd = 5.8 cm = a 5.8 = {(0.45 ´ 2) + (0.75 ´ 2) + (1.15 ´ 2) + (0.90 ´ 2) + (0.80 ´ 2) + (0.50 ´ 2)} – 12 j = 9.1 – 12 j j = 3.3/12 = 0.275 cm/h By inspection of row 5 of Table 3. 12, Mc = number of pulses having Ii ³ j, that is Ii ³ 0.275 cm/h is 6. Thus Mc = 6 = M. Hence assumed M is OK. The j-index of the storm is 0.275 cm/h and the duration of rainfall excess = te = 12 hours. The hyetograph of the storm, losses, the rainfall excess and the duration of rainfall excess are shown in Fig. 3.17.

W- Index In an attempt to refine the j-index the initial losses are separated from the total abstractions and an average value of infiltration rate, called W-index, is defined as P - R - Ia W= (3.29) te where P = total storm precipitation (cm) R = total storm runoff (cm) Ia = Initial losses (cm) te = duration of the rainfall excess, i.e. the total time in which the rainfall intensity is greater than W (in hours) and W = defined average rate of infiltration (cm). Since Ia rates are difficult to obtain, the accurate estimation of W-index is rather difficult. The minimum value of the W-index obtained under very wet soil conditions, representing the constant minimum rate of infiltration of the catchment, is known as Wmin. It is to be noted that both the j-index and W-index vary from storm to storm. Computation of W-index To compute W-index from a given storm hyetograph with known values of Ia and runoff R, the following procedure is followed: (i) Deduct the initial loss Ia from the storm hyetograph pulses starting from the first pulse

Abstractions from Precipitation

95

(ii) Use the resulting hyetograph pulse diagram and follow the procedure indicated in Sec. 3.19.1. Thus the procedure is exactly same as in the determination of j-index except for the fact that the storm hyetograph is appropriately modified by deducting Ia. j-index for Practical use The j-index for a catchment, during a storm, depends in general upon the soil type, vegetal cover, initial moisture condition, storm duration and intensity. To obtain complete information on the interrelationship between these factors, a detailed expensive study of the catchment is necessary. As such, for practical use in the estimation of flood magnitudes due to critical storms a simplified relationship for j-index is adopted. As the maximum flood peaks are invariably produced due to long storms and usually in the wet season, the initial losses are assumed to be negligibly small. Further, only the soil type and rainfall are found to be critical in the estimate of the j-index for maximum flood producing storms. On the basis of rainfall and runoff correlations, CWC1 has found the following relationships for the estimation of j-index for flood producing storms and soil conditions prevalent in India R = a I1.2 (3.30) I -R (3.31) j= 24 where R = runoff in cm from a 24-h rainfall of intensity I cm/h and a = a coefficient which depends upon the soil type as indicated in Table 3.13. In estimating the maximum floods for design purposes, in the absence of any other data, a j-index value of 0.10 cm/h can be assumed. Table 3.13 Variation of Coefficient a in Eq. 3.30 Sl. No. 1. 2. 3. 4. 5.

Type of Soil

Coefficient a

Sandy soils and sandy loam Coastal alluvium and silty loam Red soils, clayey loam, grey and brown alluvium Black–cotton and clayey soils Hilly soils

0.17 to 0.25 0.25 to 0.34 0.42 0.42 to 0.46 0.46 to 0.50

REFERENCES 1. Central Water Commission, India, Estimation of Design Flood Peak, Flood Estimation Directorate, Report No. 1/73, New Delhi, 1973. 2. Chow, V.T. (Ed.), Handbook of Applied Hydrology, McGraw-Hill, New York, NY., 1964. 3. Allen, R.G. et al., “Crop Evapotranspiration—Guidelines for Computing Crop–Water Requirements”, Irrigation and Drainage Paper 56, UN FAO, Rome, Italy, 1988. 4. Gray, D.M., Principles of Hydrology, Water Inf. Center, Huntington, NY, 1970. 5. Rao, K.N. et al., “Potential Evapotranspiration (PE) over India”, Symp. on Water Resources, I.I.Sc. Bangalore, India, 1971, 99 A 2-1-14. (Also Sc. Rep. No. 136, IMD, Feb. 1971). 6. Soil Conservation Div., Handbook of Hydrology, Min. of Agriculture, GOI, 1972. 7. Weisner, C.J., Hydrometeorology, Chapman and Hall, U.K., 1970. 8. Min. of Water Resources, GOI, Report of The National Commission for Integrated Water Resources Development, Vol.-1, New Delhi, Sept. 1999.

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REVISION QUESTIONS 3.1 3.2 3.3 3.4 3.5 3.6 3.7 3.8 3.9 3.10 3.11 3.12 3.13 3.14 3.15

Discuss briefly the various abstractions from precipitation. Explain briefly the evaporation process. Discuss the factors that affect the evaporation from a water body. Describe a commonly used evaporimeter. Explain the energy budget method of estimating evaporation from a lake. Discuss the importance of evaporation control of reservoirs and possible methods of achieving the same. Describe the factors affecting evapotranspiration process. List the various data needed to use Penman’s equation for estimating the potential evapotranspiration from a given area. Describe briefly (a) Reference crop evapotranspiration and (b) Actual evapotrans-piration. Explain briefly the infiltration process and the resulting soil moisture zones in the soil. Discuss the factors affecting the infiltration capacity of an area. Describe the commonly used procedures for determining the infiltration characteristics of a plot of land. Explain clearly the relative advantages and disadvantages of the enumerated methods. Describe various models adopted to represent the variation of infiltration capacity with time. Explain a procedure for fitting Horton’s infiltration equation for experimental data from a given plot. Distinguish between (a) Infiltration capacity and infiltration rate (b) Actual and potential evapotranspiration (c) Field capacity and permanent wilting point (d) Depression storage and interception

PROBLEMS 3.1

3.2

3.3

3.4

Calculate the evaporation rate from an open water source, if the net radiation is 300 W/m2 and the air temperature is 30° C. Assume value of zero for sensible heat, ground heat flux, heat stored in water body and advected energy. The density of water at 30° C = 996 kg/m3. [Hint: Calculate latent heat of vapourisation L by the formula: L = 2501 – 2.37 T (kJ/kg), where T = temperature in °C.] A class A pan was set up adjacent to a lake. The depth of water in the pan at the beginning of a certain week was 195 mm. In that week there was a rainfall of 45 mm and 15 mm of water was removed from the pan to keep the water level within the specified depth range. If the depth of the water in the pan at the end of the week was 190 mm calculate the pan evaporation. Using a suitable pan coefficient estimate the lake evaporation in that week. A reservoir has an average area of 50 km2 over an year. The normal annual rainfall at the place is 120 cm and the class A pan evaporation is 240 cm. Assuming the land flooded by the reservoir has a runoff coefficient of 0.4, estimate the net annual increase or decrease in the streamflow as a result of the reservoir. At a reservoir in the neighbourhood of Delhi the following climatic data were observed. Estimate the mean monthly and annual evaporation from the reservoir using Meyer’s formula.

Month

Temp. (°C)

Relative humidity (%)

Wind velocity at 2 m above GL (km/h)

Jan Feb Mar

12.5 15.8 20.7

85 82 71

4.0 5.0 5.0 (Contd.)

Abstractions from Precipitation

97

(Contd.) Apr May Jun Jul Aug Sep Oct Nov Dec 3.5

3.6

3.7

3.8

27.0 31.0 33.5 30.6 29.0 28.2 28.8 18.9 13.7

48 41 52 78 86 82 75 77 73

5.0 7.8 10.0 8.0 5.5 5.0 4.0 3.6 4.0

For the lake in Prob. 3.4, estimate the evaporation in the month of June by (a) Penman formula and (b) Thornthwaite equation by assuming that the lake evaporation is the same as PET, given latitude = 28° N and elevation = 230 m above MSL. Mean observed sunshine = 9 h/day. A reservoir had an average surface area of 20 km2 during June 1982. In that month the mean rate of inflow = 10 m3/s, outflow = 15 m3/s, monthly rainfall = 10 cm and change in storage = 16 million m3. Assuming the seepage losses to be 1.8 cm, estimate the evaporation in that month. For an area in South India (latitude = 12° N), the mean monthly temperatures are given. Month

June

July

Aug

Sep

Oct

Temp (°C)

31.5

31.0

30.0

29.0

28.0

Calculate the seasonal consumptive use of water for the rice crop in the season June 16 to October 15, by using the Blaney–Criddle formula. A catchment area near Mysore is at latitude 12° 18¢ N and at an elevation of 770 m. The mean monthly temperatures are given below. Month

Jan Feb Mar Apr May Jun

Jul

Aug Sep

Oct Nov Dec

Mean monthly temp. (°C) 22.5 24.5 27.0 28.0 27.0 25.0 23.5 24.0 24.0 24.5 23.0 22.5 Calculate the monthly and annual PET for this catchment using the Thornthwaite formula. A wheat field has maximum available moisture of 12 cm. If the reference evapotranspiration is 6.0 mm/day, estimate the actual evapotranspiration on Day 2, Day 7 and Day 9 after irrigation. Assume soil-water depletion factor p = 0.20 and crop factor K = 0.65. 3.10 Results of an infiltrometer test on a soil are given below. Determine the Horton’s infiltration capacity equation for this soil. 3.9

Time since start in (h) Infiltration capacity in cm/h

0.25 5.6

0.50 3.20

0.75 2.10

1.00 1.50

1.25 1.20

1.50 1.10

1.75 1.0

2.0 1.0

3.11 Results of an infiltrometer test on a soil are given below. Determine the best values of the parameters of Horton’s infiltration capacity equation for this soil.

98

Engineering Hydrology Time since start in minutes Cumulative infiltration in mm

5

10

15

20

30

21.5

37.7

52.2

65.8

78.4

40

60

80

100

89.5 101.8 112.6 123.3

3.12 Results of an infiltrometer test on a soil are as follows: Time since start in minutes Cumulative infiltration in mm

5

10

15

20

30

40

1.00

1.80

2.50

3.10

4.20

5.10

60

120

150

6.60 11.00 12.90

Determine the parameters of (i) Kostiakov’s equation, (ii) Green–Ampt equation, and (iii) Philips equation 3.13 Determine the best values of the parameters of Horton’s infiltration capacity equation for the following data pertaining to infiltration tests on a soil using double ring infiltrometer. Time since start in minutes Cumulative infiltration in mm

5

10

15

25

40

60

75

90

110 130

21.0 36.0 47.6 56.9 63.8 69.8 74.8 79.3 87.0 92.0

3.14 For the infiltration data set given below, establish (a) Kostiakov’s equation, (b) Philips equation, and (c) Green–Ampt equation. Time since start in minutes Cumulative Infiltration in mm

10

20

30

50

80

120

160

200

280

360

9.8

18.0

25.0

38.0

55.0

76.0

94.0 110.0 137.0 163.0

3.15 Following table gives the values of a field study of infiltration using flooding type infiltrometer. (a) For this data plot the curves of (i) infiltration capacity fp (mm/h) vs time (h) on a log–log paper and obtain the equation of the best fit line, and (ii) Cumulative infiltration (mm) Fp vs time (h) on a semi-log paper and obtain the equation of the best fit line. (b) Establish Horton’s infiltration capacity equation for this soil. Time since start in minutes Cumulative Infiltration in cm

2

10

30

60

90

120

240

360

7.0

20.0

33.5

37.8

39.5

41.0

43.0

45.0

3.16 The infiltration capacity of a catchment is represented by Horton’s equation as fp = 0.5 + 1.2e–0.5t where fp is in cm/h and t is in hours. Assuming the infiltration to take place at capacity rates in a storm of 4 hours duration, estimate the average rate of infiltration for the duration of the storm. 3.17 The infiltration process at capacity rates in a soil is described by Kostiakov’s equation as Fp = 3.0 t0.7 where Fp is cumulative infiltration in cm and t is time in hours. Estimate the infiltration capacity at (i) 2.0 h and (ii) 3.0 h from the start of infiltration.

Abstractions from Precipitation

99

3.18 The mass curve of an isolated storm in a 500 ha watershed is as follows: Time from start (h) Cumulative rainfall (cm)

2

4

6

8

0.8

2.6

2.8

4.1

10

12

14

16

18

7.3 10.8 11.8 12.4 12.6

If the direct runoff produced by the storm is measured at the outlet of the watershed as 0.340 Mm3, estimate the j-index of the storm and duration of rainfall excess. 3.19 The mass curve of an isolated storm over a watershed is given below. Time from start (h) Cummulative rainfall (cm)

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

0.25 0.50 1.10 1.60 2.60 3.50 5.70 6.50 7.30 7.70

If the storm produced a direct runoff of 3.5 cm at the outlet of the watershed, estimate the j-index of the storm and duration of rainfall excess. 3.20 In a 140-min storm the following rates of rainfall were observed in successive 20-min intervals: 6.0, 6.0, 18.0, 13.0, 2.0, 2.0 and 12.0 mm/h. Assuming the j-index value as 3.0 mm/h and an initial loss of 0.8 mm, determine the total rainfall, net runoff and W-index for the storm. 3.21 The mass curve of rainfall of duration 100 min is given below. If the catchment had an initial loss of 0.6 cm and a j-index of 0.6 cm/h, calculate the total surface runoff from the catchment.

Time from start of rainfall (min) Cummulative rainfall (cm)

0 0

20 0.5

40 1.2

60 2.6

80 3.3

100 3.5

3.22 An isolated 3-h storm occurred over a basin in the following fashion: % of catchment area

j–index (cm/h)

20 30 50

1.00 0.75 0.50

1st hour 0.8 0.7 1.0

Rainfall (cm) 2nd hour 3rd hour 2.3 2.1 2.5

1.5 1.0 0.8

Estimate the runoff from the catchment due to the storm.

OBJECTIVE QUESTIONS 3.1 If ew and ea are the saturated vapour pressures of the water surface and air respectively, the Dalton’s law for evaporation EL in unit time is given by EL = (b) K ew ea (c) K (ew – ea) (d) K (ew + ea) (a) (ew – ea) 3.2 The average pan coefficient for the standard US Weather Bureau class A pan is (a) 0.85 (b) 0.70 (c) 0.90 (d) 0.20 3.3 A canal is 80 km long and has an average surface width of 15 m. If the evaporation measured in a class A pan is 0.5 cm/day, the volume of water evaporated in a month of 30 days is (in m3) (a) 12600 (b) 18000 (c) 180000 (d) 126000 3.4 The ISI standard pan evaporimeter is the (a) same as the US class A pan (b) has an average pan coefficient value of 0.60

100 Engineering Hydrology

3.5 3.6 3.7 3.8 3.9 3.10 3.11

3.12 3.13

3.14

3.15

3.16 3.17 3.18

(c) has less evaporation than a US class A pan (d) has more evaporation than a US class A pan. The chemical that is found to be most suitable as water evaporation inhibitor is (a) ethyl alcohol (b) methyl alcohol (c) cetyl alcohol (d) butyl alcohol. Wind speed is measured with (a) a wind vane (b) a heliometer (c) Stevenson box (d) anemometer If the wind velocity at a height of 2 m above ground is 5.0 kmph, its value at a height of 9 m above ground can be expected to be in km/h about (a) 9.0 (b) 6.2 (c) 2.3 (d) 10.6 Evapotranspiration is confined (a) to daylight hours (b) night-time only (c) land surfaces only (d) none of these. Lysimeter is used to measure (a) infiltration (b) evaporation (c) evapotranspiration (d) vapour pressure. The highest value of annual evapotranspiration in India is at Rajkot, Gujarat. Here the annual PET is about (a) 150 cm (b) 150 mm (c) 210 cm (d) 310 cm. Interception losses (a) include evaporation, through flow and stemflow (b) consists of only evaporation loss (c) includes evaporation and transpiration losses (d) consists of only stemflow. The infiltration capacity of a soil was measured under fairly identical general conditions by a flooding type infiltrometer as ff and by a rainfall simulator as fr. One can expect (a) ff = fr (b) ff > fr (c) ff < fr (d) no fixed pattern. A watershed 600 ha in area experienced a rainfall of uniform intensity 2.0 cm/h for duration of 8 hours. If the resulting surface runoff is measured as 0.6 Mm3, the average infiltration capacity during the storm is (a) 1.5 cm/h (b) 0.75 cm/h (c) 1.0 cm/h (d) 2.0 cm/h In a small catchment the infiltration rate was observed to be 10 cm/h at the beginning of the rain and it decreased exponentially to an equilibrium value of 1.0 cm/h at the end of 9 hours of rain. If a total of 18 cm of water infiltered during 9 hours interval, the value of the decay constant Kh in Horton’s infiltration equation in (h–1) units is (a) 0.1 (b) 0.5 (c) 1.0 (d) 2.0 In Horton’s infiltration equation fitted to data from a soil, the initial infiltration capacity is 10 mm/h, final infiltration capacity is 5 mm/h and the exponential decay constant is 0.5 h–1. Assuming the infiltration takes place at capacity rates, the total infiltration depth for a uniform storm of duration 8 hours is (a) 40 mm (b) 60 mm (c) 80 mm (d) 90 mm The rainfall on five successive days on a catchment was 2, 6, 9, 5 and 3 cm. If the j-index for the storm can be assumed to be 3 cm/day, the total direct runoff from the catchment is (a) 20 cm (b) 11 cm (c) 10 cm (d) 22 cm A 6-h storm had 6 cm of rainfall and the resulting runoff was 3.0 cm. If the j-index remains at the same value the runoff due to 12 cm of rainfall in 9 h in the catchment is (a) 9.0 cm (b) 4.5 cm (c) 6.0 cm (d) 7.5 cm For a basin, in a given period Dt, there is no change in the groundwater and soil water status. If P = precipitation, R = total runoff, E = Evapotranspiration and DS = increase in the surface water storage in the basin, the hydrological water budget equation states (a) P = R – E ± DS (b) R = P + E – DS (c) P = R + E + DS (d) None of these

Chapter

4

STREAMFLOW MEASUREMENT

4.1 INTRODUCTION Streamflow representing the runoff phase of the hydrologic cycle is the most important basic data for hydrologic studies. It was seen in the previous chapters that precipitation, evaporation and evapotranspiration are all difficult to measure exactly and the presently adopted methods have severe limitations. In contrast the measurement of streamflow is amenable to fairly accurate assessment. Interestingly, streamflow is the only part of the hydrologic cycle that can be measured accurately. A stream can be defined as a flow channel into which the surface runoff from a specified basin drains. Generally, there is considerable exchange of water between a stream and the underground water. Streamflow is measured in units of discharge (m3/ s) occurring at a specified time and constitutes historical data. The measurement of discharge in a stream forms an important branch of Hydrometry, the science and practice of water measurement. This chapter deals with only the salient streamflow measurement techniques to provide an appreciation of this important aspect of engineering hydrology. Excellent treatises1, 2, 4, 5 and a bibliography6 are available on the theory and practice of streamflow measurement and these are recommended for further details. Streamflow measurement techniques can be broadly classified into two cate-gories as (i) direct determination and (ii) indirect determination. Under each category there are a host of methods, the important ones are listed below: 1. Direct determination of stream discharge: (a) Area-velocity methods, (b) Dilution techniques, (c) Electromagnetic method, and (d) Ultrasonic method. 2. Indirect determination of streamflow: (a) Hydraulic structures, such as weirs, flumes and gated structures, and (b) Slope-area method. Barring a few exceptional cases, continuous measurement of stream discharge is very difficult. As a rule, direct measurement of discharge is a very time-consuming and costly procedure. Hence, a two step procedure is followed. First, the discharge in a given stream is related to the elevation of the water surface (Stage) through a series of careful measurements. In the next step the stage of the stream is observed routinely in a relatively inexpensive manner and the discharge is estimated by using the previously determined stage–discharge relationship. The observation of the stage is easy, inexpensive, and if desired, continuous readings can also be obtained. This method of discharge determination of streams is adopted universally.

102 Engineering Hydrology

4.2 MEASUREMENT OF STAGE The stage of a river is defined as its water-surface elevation measured above a datum. This datum can be the mean-sea level (MSL) or any arbitrary datum connected independently to the MSL.

Manual Gauges Staff Gauge The simplest of stage measurements are made by noting the elevation of the water surface in contact with a fixed graduated staff. The staff is made of a durable material with a low coefficient of expansion with respect to both temperature and moisture. It is fixed rigidly to a structure, such as an abutment, pier, wall, etc. The staff may be vertical or inclined with clearly and accurately graduated permanent markings. The markings are distinctive, easy to read from a distance and are similar to those on a surveying staff. Sometimes, it may not be possible to read the entire range of water-surface elevations of a stream by a single gauge and in such cases the gauge is built in sections at different locations. Such gauges are called sectional gauges (Fig. 4.1). When installing sectional gauges, care must be taken to provide an overlap between various gauges and to refer all the sections to the same common datum.

Fig. 4.1 Staff Gauge Wire Gauge It is a gauge used to measure the water-surface elevation from above the surface such as from a bridge or similar structure. In this a weight is lowered by a reel to touch the water surface. A mechanical counter measures the rotation of the wheel which is proportional to the length of the wire paid out. The operating range of this kind of gauge is about 25 m.

Automatic Stage Recorders The staff gauge and wire gauge described earlier are manual gauges. While they are simple and inexpensive, they have to be read at frequent intervals to define the variation of stage with time accurately. Automatic stage recorders overcome this basic objection of manual staff gauges and find considerable use in stream-flow measurement practice. Two typical automatic stage recorders are described below. Float-Gauge Recorder The Float-operated stage recorder is the most common type of automatic stage recorder in use. In this, a float operating in a stilling well is balanced by means of a counterweight over the pulley of a recorder. Displacement of the float due to the rising or lowering of the water-surface elevation causes an angular displacement of the pulley and hence of the input shaft of the recorder.

Streamflow Measurement

103

Mechanical linkages convert this angular displacement to the linear displacement of a pen to record over a drum driven by clockwork. The pen traverse is continuous with automatic reversing when it reaches the full width of the chart. A clockwork mechanism runs the recorder for a day, week or fortnight and provides a continuous plot of stage vs time. A good instruFig. 4.2 Stilling well Installation ment will have a largesize float and least friction. Improvements over this basic analogue model consists of models that give digital signals recorded on a storage device or transmit directly onto a central data-processing centre. To protect the float from debris and to reduce the water surface wave effects on the recording, stilling wells are provided in all floattype stage recorder installations. Figure 4.2 shows a typical stilling well installation. Note the intake pipes that communicate with the river and flushing arrangement to flush these intake pipes off the sediment and debris occasionally. The water-stage recorder has to be located above the highest water level expected in the stream to prevent it from getting inundated during floods. Further, the instrument must be prop- Fig. 4.3 Water-depth recorder— Stevens Type F recorder erly housed in a suitable enclosure to protect it (Courtesy: Leupold and from weather elements and vandalism. On account of these, the water-stage-recorder instalStevens, Inc. Beaverton, lations prove to be costly in most instances. A Oregon, USA) water-depth recorder is shown in Fig. 4.3. Bubble Gauge In this gauge compressed air or gas is made to bleed out at a very small rate through an outlet placed at the bottom of the river [Figs. 4.4, 4.5 and 4.6]. A pressure gauge measures the gas pressure which in turn is equal to the water column above the outlet. A small change in the water-surface elevation is felt as a change in pressure from the present value at the pressure gauge and this in turn is adjusted by a servo-mechanism to bring the gas to bleed at the original rate under the new head. The pressure gauge reads the new water depth which is transmitted to a recorder. The bubble gauge has certain specific advantages over a float operated water stage recorder and these can be listed as under:

104 Engineering Hydrology

Fig. 4.4 Bubble Gauge

Fig. 4.5 Bubble Gauge Installation— Telemnip (Courtesy : Neyrtec, Grenoble, France) 1. 2. 3. 4.

Fig. 4.6 Bubble Gauge—Stevens Manometer Servo (Courtesy : Leupold and Stevens, Inc. Beaverton, Oregon, USA)

there is no need for costly stilling wells; a large change in the stage, as much as 30 m, can be measured; the recorder assembly can be quite far away from the sensing point; and due to constant bleeding action there is less likelihood of the inlet getting blocked or choked.

Stage Data The stage data is often presented in the form of a plot of stage against chrono-logical time (Fig. 4.7) known as stage hydrograph. In addition to its use in the determination of stream discharge, stage data itself is of importance in design of hydraulic structures, flood warning and flood-protection works. Reliable long-term stage data corresponding

Fig. 4.7 Stage Hydrograph

Streamflow Measurement

105

to peak floods can be analysed statistically to estimate the design peak river stages foruse in the design of hydraulic structures, such as bridges, weirs, etc. Historic flood stages are invaluable in the indirect estimation of corresponding flood discharges. In view of these multifarious uses, the river stage forms an important hydrologic parameter chosen for regular observation and recording.

4.3 MEASUREMENT OF VELOCITY The measurement of velocity is an important aspect of many direct stream flow measurement techniques. A mechanical device, called current meter, consisting essentially of a rotating element is probably the most commonly used instrument for accurate determination of the stream-velocity field. Approximate stream velocities can be determined by floats.

Current Meters The most commonly used instrument in hydrometry to measure the velocity at a point in the flow cross-section is the current meter. It consists essentially of a rotating element which rotates due to the reaction of the stream current with an angular velocity proportional to the stream velocity. Historically, Robert Hooke (1663) invented a propeller-type current meter to measure the distance traversed by a ship. The presentday cup-type instrument and the electrical make-and-break mechanism were invented by Henry in 1868. There are two main types of current meters. 1. Vertical-axis meters, and 2. Horizontal-axis meters. Vertical-Axis Meters These instruments consist of a series of conical cups mounted around a vertical axis [Figs. 4.8 and 4.9]. The cups rotate in a Fig. 4.8 Vertical-axis Current Meter horizontal plane and a cam attached to the vertical axial spindle records generated signals proportional to the revolutions of the cup assembly. The Price current meter and Gurley current meter are typical instruments under this category. The normal range of velocities is from 0.15 to 4.0 m/s. The accuracy of these instruments is about 1.50% at the threshold value and improves to about 0.30% at speeds in excess of 1.0 m/s. Vertical-axis instruments have the disadvantage that they cannot be used in situ- Fig. 4.9 Cup-type Current Meter with Sounding Weight— ations where there are appreciable verti‘Lynx’ Type cal components of velocities. For exam(Courtesy : Lawrence and Mayo (Inple, the instrument shows a positive vedia) New Delhi) locity when it is lifted vertically in still water.

106 Engineering Hydrology Horizontal-Axis Meters These meters consist of a propeller mounted at the end of horizontal shaft as shown in Fig. 4.10 and Fig. 4.11. These come in a wide variety of size with propeller diameters in the range 6 to 12 cm, and can register velocities in the range of 0.15 to 4.0 m/s. Ott, Neyrtec [Fig. 4.12] and Watttype meters are typical instruments under this kind. These meters are fairly rugged and are not affected by oblique flows of as much as 15°. The accuracy of the instrument is about 1% at the threshold value and is about 0.25% at a velocity of 0.3 m/s and above. A current meter is so designed that its rotation speed varies linearly with the stream velocity v at the location of the instrument. A typical relationship is v = aNs + b (4.1) Fig. 4.10 Propeller-type Current Meter—Neyrtec Type with where v = stream velocity at the instruSounding Weight ment location in m/s, Ns = revolutions per second of the meter and a, b = constants of the meter. Typical values of a and b for a standard size 12.5 cm diameter Price meter (cup-type) is a = 0.65 and b = 0.03. Smaller meters of 5 cm diameter cup assembly called pigmy meters run faster and are useful in measuring small velocities. The values of the meter constants Fig. 4.11 Horizontal-axis Current for them are of the order of a = 0.30 and Meter b = 0.003. Further, each instrument has a threshold velocity below which Eq. (4.1) is not applicable. The instruments have a provision to count the number of revolutions in a known interval of time. This is usually accomplished by the making and breaking of an electric circuit either mechanically or electro-magnetically at each revolution of the shaft. In older model instruments the breaking of the circuit would be counted through an audible sharp signal (“tick”) heard on a headphone. The revolutions per second is calculated by counting the number of such signals in a known interval of time, usually about 100 s. Presentday models employ electro-magnetic counters with digital or analogue displays.

Calibration The relation between the stream velocity and revolutions per second of the meter as in Eq. (4.1) is called the calibration equation. The calibration equation is unique to each instrument and is determined by towing the instrument in a special tank. A towing tank is a long channel containing still water with arrangements for moving a carriage

Streamflow Measurement

Fig. 4.12(a)

Neyrtec Type Current Meter for use in Wading (Courtesy: Neyrtec, Grenoble, France)

Fig. 4.12(b)

107

Neyrtec Type Meter in a Cableway

longitudinally over its surface at constant speed. The instrument to be calibrated is mounted on the carriage with the rotating element immersed to a specified depth in the water body in the tank. The carriage is then towed at a predetermined constant speed (v) and the corresponding average value of revolutions per second (Ns) of the instruments determined. This experiment is repeated over the complete range of velocities and a best-fit linear relation in the form of Eq. (4.1) obtained. The instruments are designed for rugged use and hence the calibration once done lasts for quite some time. However, from the point of view of accuracy it is advisable to check the instrument calibration once in a while and whenever there is a suspicion that the instrument is damaged due to bad handling or accident. In India excellent towing-tank facilities for calibration of current meters exist at the Central Water and Power Research Station, Pune and the Indian Institute of Technology, Madras.

Field Use The velocity distribution in a stream across a vertical section is logarithmic in nature. In a rough turbulent flow the velocity distribution is given by

æ 30 y ö v = 5.75 v* log10 ç (4.2) è k s ÷ø where v = velocity at a point y above the bed, v* = shear velocity and ks = equivalent sand-grain roughness. To accurately determine the average velocity in a vertical section, one has to measure the velocity at a large number of points on the vertical. As it is time-consuming, certain simplified procedures have been evolved. l In shallow streams of depth up to about 3.0 m, the velocity measured at 0.6 times the depth of flow below the water surface is taken as the average velocity v in the vertical,

108 Engineering Hydrology (4.3) v = v0.6 This procedure is known as the single-point observation method. l In moderately deep streams the velocity is observed at two points; (i) at 0.2 times the depth of flow below the free surface (v0.2) and (ii) at 0.8 times the depth of flow below the free surface (v0.8). The average velocity in the vertical v is taken as v0.2 + v0.8 (4.4) v = 2 l In rivers having flood flows, only the surface velocity (vs) is measured within a depth of about 0.5 m below the surface. The average velocity v is obtained by using a reduction factor K as (4.5) v = Kvs The value of K is obtained from observations at lower stages and lie in the range of 0.85 to 0.95. In small streams of shallow depth the current meter is held at the requisite depth below the surface in a vertical by an observer who stands in the water. The arrangement, called wading is quite fast but is obviously applicable only to small streams. In rivers flowing in narrow gorges in well-defined channels a cableway is stretched from bank to bank well above the flood level. A carriage moving over the cableway is used as the observation platform. Bridges, while hydraulically not the best locations, are advantageous from the point of view of accessibility and transportation. Hence, railway and road bridges are frequently employed as gauging stations. The velocity measurement is performed on the downstream portion of the bridge to minimize the instrument damage due to drift and knock against the bridge piers. For wide rivers, boats are the most satisfactory aids in current meter measurement. A cross-sectional line is marked by distinctive land markings and buoys. The position of the boat is determined by using two theodolites on the bank through an intersection method. Use of total station simplifies the work considerably.

Sounding Weights Current meters are weighted down by lead weights called sounding weights to enable them to be positioned in a stable manner at the required location in flowing water. These weights are of streamlined shape with a fin in the rear (Fig. 4.8) and are connected to the current meter by a hangar bar and pin assembly. Sounding weights come in different sizes and the minimum weight is estimated as W = 50 v d (4.6) where W = minimum weight in N, v = average stream velocity in the vertical in m/s and d = depth of flow at the vertical in metres.

Velocity Measurement by Floats A floating object on the surface of a stream when timed can yield the surface velocity by the relation S (4.7) vs = t

Streamflow Measurement

109

where S = distance travelled in time t. This method of measuring velocities while primitive still finds applications in special circumstances, such as: (i) a small stream in flood, (ii) small stream with a rapidly changing water surface, and (iii) preliminary or exploratory surveys. While any floating object can be used, normally specially made leakproof and easily Fig. 4.13 Floats identifiable floats are used (Fig. 4.13). A simple float moving on stream surface is called surface float. It is easy to use and the mean velocity is obtained by multiplying the observed surface velocity by a reduction coefficient as in Eq. (4.5). However, surface floats are affected by surface winds. To get the average velocity in the vertical directly, special floats in which part of the body is under water are used. Rod float (Fig. 4.13), in which a cylindrical rod is weighed so that it can float vertically, belongs to this category. In using floats to observe the stream velocity a large number of easily identifiable floats are released at fairly uniform spacings on the width of the stream at an upstream section. Two sections on a fairly straight reach are selected and the time to cross this reach by each float is noted and the surface velocity calculated.

4.4 AREA-VELOCITY METHOD This method of discharge measurement consists essentially of measuring the area of cross-section of the river at a selected section called the gauging site and measuring the velocity of flow through the cross-sectional area. The gauging site must be selected with care to assure that the stage-discharge curve is reasonably constant over a long period of about a few years. Towards this the following criteria are adopted. l The stream should have a well-defined cross-section which does not change in various seasons. l It should be easily accessible all through the year. l The site should be in a straight, stable reach. l The gauging site should be free from backwater effects in the channel. At the selected site the section line is marked off by permanent survey markings and the cross-section determined. Towards this the depth at various locations are measured by sounding rods or sounding weights. When the stream depth is large or when quick and accurate depth measurements are needed, an electroacoustic instrument called echo-depth recorder is used. In this a high frequency sound wave is sent down by a transducer kept immersed at the water surface and the echo reflected by the bed is also picked up by the same transducer. By comparing the time interval between the transmission of the signal and the receipt of its echo, the distance to the bed is obtained and is indicated or recorded in the instrument. Echo-depth recorders are particularly advantageous in high-velocity streams, deep streams and in streams with soft or mobile beds. For purposes of discharge estimation, the cross-section is considered to be divided into a large number of subsections by verticals (Fig. 4.14). The average velocity in these subsections are measured by current meters or floats. It is quite obvious that the

110 Engineering Hydrology

Fig. 4.14 Stream Section for Area-velocity Method accuracy of discharge estimation increases with the number of subsections used. However, the larger the number of segments, the larger is the effort, time and expenditure involved. The following are some of the guidelines to select the number of segments. l The segment width should not be greater than 1/15 to 1/20 of the width of the river. l The discharge in each segment should be less than 10% of the total discharge. l The difference of velocities in adjacent segments should not be more than 20%. It should be noted that in natural rivers the verticals for velocity measurement are not necessarily equally spaced. The area-velocity method as above using the current meter is often called as the standard current meter method.

Calculation of Discharge Figure 4.14 shows the cross section of a river in which N – 1 verticals are drawn. The velocity averaged over the vertical at each section is known. Considering the total area to be divided into N – 1 segments, the total discharge is calculated by the method of mid-sections as follows. Q= where

N -1

å D Qi

(4.8)

i =1

DQi = discharge in the ith segment

æ1 = (depth at the ith segment) ´ ç width to the left è2 +

æ 1 width to right ç ´ (average velocity at the ith vertical) è 2

æ Wi Wi + 1 ö + D Qi = yi ´ ç for i = 2 to (N – 2) (4.9) ÷ ´ vi è 2 2 ø For the first and last sections, the segments are taken to have triangular areas and area calculated as DA1 = W1 × y1 where

W2 ö æ çèW1 + ÷ 2 ø W1 = 2 W1

2

and

DAN = WN -1 × yN–1

Streamflow Measurement

where to get

W N -1 =

WN - 1 ö æ çèWN + ÷ 2 ø

111

2

2 WN

D Q1 = v1 × D A1 and D QN – 1 = vN - 1 D AN – 1

(4.10)

EXAMPLE 4.1 The data pertaining to a stream-gauging operation at a gauging site are given below. The rating equation of the current meter is v = 0.51 Ns + 0.03 m/s where Ns = revolutions per second. Calculate the discharge in the stream. Distance from left water edge (m) Depth (m) Revolutions of a current meter kept at 0.6 depth Duration of observation (s)

0 0

1.0 1.1

3.0 2.0

5.0 2.5

7.0 2.0

9.0 1.7

11.0 1.0

12.0 0

39

58

112

90

45

30

100

100

150

150

100

100

SOLUTION: The calculations are performed in a tabular form. For the first and last sections, æ1 + 2 ö è 2ø W= Average width, 2 ´1 For the rest of the segments,

2

= 2.0 m

2 2 W = æ + ö = 2.0 m è 2 2ø Since the velocity is measured at 0.6 depth, the measured velocity is the average velocity at that vertical ( v ). The calculation of discharge by the mid-section method is shown in tabular form below:

Distance Average from left width water edge W (m) (m) 0 1 3 5 7 9 11 12

0 2 2 2 2 2 2 0

Depth y (m)

Ns = Rev./second

Velocity v (m/s)

0 1.10 2.00 2.50 2.00 1.70 1.00 0.00

0.390 0.580 0.747 0.600 0.450 0.300

0.2289 0.3258 0.4110 0.3360 0.2595 0.1830

Discharge in the stream = 6.454 m3/s

Sum =

Segmental discharge DQi (m3/s) 0.0000 0.5036 1.3032 2..0549 1.3440 0.8823 0.3660 0.0000 6.45393

112 Engineering Hydrology

Moving-Boat Method Discharge measurement of large alluvial rivers, such as the Ganga, by the standard current meter method is very timeconsuming even when the flow is low or moderate. When the river is in spate, it is almost impossible to use the standard current meter technique due to the difficulty of keeping the boat stationary on the fast-moving surface of the stream for observation purposes. It is in such circumstance that the moving-boat techniques prove very helpful. Fig. 4.15 Moving-boat Method In this method a special propeller-type current meter which is free to move about a vertical axis is towed in a boat at a velocity vb at right angles to the stream flow. If the flow velocity is vf the meter will align itself in the direction of the resultant velocity vR making an angle q with the direction of the boat (Fig. 4.15). Further, the meter will register the velocity vR. If vb is normal to vf, vb = vR cos q and vf = vR sin q If the time of transit between two verticals is D t, then the width between the two verticals (Fig. 4.15) is W = vb Dt The flow in the sub-area between two verticals i and i + 1 where the depths are yi and yi + 1 respectively, by assuming the current meter to measure the average velocity in the vertical, is æ yi + yi + 1 ö DQi = ç ÷ø Wi + 1 vf è 2

æ yi + yi + 1 ö 2 DQi = ç (4.11) ÷ø vR sin q × cos q × Dt è 2 Thus by measuring the depths yi, velocity vR and q in a reach and the time taken to cross the reach D t, the discharge in the sub-area can be determined. The summation of the partial discharges D Qi over the whole width of the stream gives the stream discharge (4.12) Q = S D Qi In field application a good stretch of the river with no shoals, islands, bars, etc. is selected. The cross-sectional line is defined by permanent landmarks so that the boat can be aligned along this line. A motor boat with different sizes of outboard motors for use in different river stages is selected. A special current meter of the propeller-type, in which the velocity and inclination of the meter to the boat direction q in the horizontal plane can be measured, is selected. The current meter is usually immersed at a depth of 0.5 m from the water surface to record surface velocities. To mark the various vertical sections and know the depths at these points, an echo-depth recorder is used. In a typical run, the boat is started from the water edge and aligned to go across the cross-sectional line. When the boat is in sufficient depth of water, the instruments are lowered. The echo-depth recorder and current meter are commissioned. A button on i.e.

Streamflow Measurement

113

the signal processor when pressed marks a distinctive mark line on the depth vs time chart of the echo-depth recorder. Further, it gives simultaneously a sharp audio signal to enable the measuring party to take simultaneous readings of the velocity vR and the inclination q. A large number of such measurements are taken during the traverse of the boat to the other bank of the river. The operation is repeated in the return journey of the boat. It is important that the boat is kept aligned along the cross-sectional line and this requires considerable skill on the part of the pilot. Typically, a river of about 2 km stretch takes about 15 min for one crossing. A number of crossings are made to get the average value of the discharge. The surface velocities are converted to average velocities across the vertical by applying a coefficient [Eq. (4.5)]. The depths yi and time intervals Dt are read from the echo-depth recorder chart. The discharge is calculated by Eqs. (4.11) and (4.12). In practical use additional coefficients may be needed to account for deviations from the ideal case and these depend upon the actual field conditions.

4.5

DILUTION TECHNIQUE OF STREAMFLOW MEASUREMENT

The dilution method of flow measurement, also known as the chemical method depends upon the continuity principle applied to a tracer which is allowed to mix completely with the flow. Consider a tracer which does not react with the fluid or boundary. Let C0 be the small initial concentration of the tracer in the streamflow. At Section 1 a small quantity (volume "1)” of high concentra-tion C1 of this tracer is added as shown in Fig. 4.16. Let Section 2 be sufficiently far away on the downstream of Section 1 so that the tracer mixes thoroughly with the fluid due to the turbulent mixing process while passing through the reach. The concentration Fig. 4.16 Sudden-injection profile taken at Section 2 is schematically Method shown in Fig. 4.16. The concentration will have a base value of C0, increases from time t1 to a peak value and gradually reaches the base value of C0 at time t2. The stream flow is assumed to be steady. By continuity of the tracer material M1 = mass of tracer added at Section 1 = "1C1 =

t2

ò

t1

Q(C2 – C0) dt +

"1 t2 - t1

t2

ò (C2 – C0) dt

t1

Neglecting the second term on the right-hand side as insignificantly small, "1 C1 Q= t2

ò (C2 - C0 ) dt

t1

(4.13)

114 Engineering Hydrology Thus the discharge Q in the stream can be estimated if for a known M1 the variation of C2 with time at Section 2 and C0 are determined. This method is known as sudden injection or gulp or integration method. Another way of using the dilution principle is to inject the tracer of concentration C1 at a constant rate Qt at Section 1. At Section 2, the concentration gradually rises from the background value of C0 at time t1 to a constant value C2 as shown in Fig. 4.17. At the steady state, the continuity equation for the tracer is QtC1 + QC0 = (Q + Qt)C2 i.e.,

Q=

Qt (C1 - C2 ) (C2 - C0 )

(4.14)

This technique in which Q is estimated by knowing C1, C2, C0 and Qt is known as constant rate injection method or plateau gauging. It is necessary to emphasise here that the dilution method of gauging is based on the assumption of steady flow. If the flow is unsteady and the flow rate changes Fig. 4.17 Constant Rate Injection appreciably during gauging, there will be Method a change in the storage volume in the reach and the steady-state continuity equation used to develop Eqs. (4.13) and (4.14) is not valid. Systematic errors can be expected in such cases.

Tracers The tracer used should have ideally the following properties 1. It should not be absorbed by the sediment, channel boundary and vegetation. It should not chemically react with any of the above surfaces and also should not be lost by evaporation. 2. It should be non-toxic. 3. It should be capable of being detected in a distinctive manner in small concentrations. 4. It should not be very expensive. The tracers used are of three main types 1. Chemicals (common salt and sodium dichromate are typical) 2. Fluorescent dyes (Rhodamine-WT and Sulpho-Rhodamine B Extra are typical) 3. Radioactive materials (such as Bromine-82, Sodium-24 and Iodine-132). Common salt can be detected with an error of ±1% up to a concentration of 10 ppm. Sodium dichromate can be detected up to 0.2 ppm concentrations. Fluorescent dyes have the advantage that they can be detected at levels of tens of nanograms per litre (~1 in 1011) and hence require very small amounts of solution for injections. Radioactive tracers are detectable up to accuracies of tens of picocuries per litre (~1 in 1014) and therefore permit large-scale dilutions. However, they involve the use of very sophisticated instruments and handling by trained personnel only. The availability of detection instrumentation, environmental effects of the tracer and overall cost of the operation are chief factors that decide the tracer to be used.

Streamflow Measurement

115

Length of Reach The length of the reach between the dosing section and sampling section should be adequate to have complete mixing of the tracer with the flow. This length depends upon the geometric dimensions of the channel cross-section, discharge and turbulence levels. An empirical formula suggested by Rimmar (1960) for estimation of mixing length for point injection of a tracer in a straight reach is L=

0.13 B 2 C (0.7 C + 2 g )

(4.15) gd where L = mixing length (m), B = average width of the stream (m), d = average depth of the stream (m), C = Chezy coefficient of roughness and g = acceleration due to gravity. The value of L varies from about 1 km for a mountain stream carrying a discharge of about 1.0 m3/s to about 100 km for river in a plain with a discharge of about 300 m3/s. The mixing length becomes very large for large rivers and is one of the major constraints of the dilution method. Artificial mixing of the tracer at the dosing station may prove beneficial for small streams in reducing the mixing length of the reach. Use The dilution method has the major advantage that the discharge is estimated directly in an absolute way. It is a particularly attractive method for small turbulent streams, such as those in mountainous areas. Where suitable, it can be used as an occasional method for checking the calibration, stage-discharge curves, etc. obtained by other methods. EXAMPLE 4.2 A 25 g/l solution of a flourescent tracer was discharged into a stream at a constant rate of 10 cm3/s. The background concentration of the dye in the stream water was found to be zero. At a downstream section sufficiently far away, the dye was found to reach an equilibrium concentration of 5 parts per billion. Estimate the stream discharge. SOLUTION: By Eq. (4.14) for the constant-rate injection method, Qt (C1 - C2 ) Q=

C2 - C0 Qt = 10 cm3/s = 10 ´ 10–6 m3/s C1 = 0.025, C2 = 5 ´ 10–9, C0 = 0 10 ´ 10-6 Q= (0.025 – 5 ´ 10–9) = 50 m3/s 5 ´ 10-9

4.6 ELECTROMAGNETIC METHOD The electromagnetic method is based on the Faraday’s principle that an emf is induced in the conductor (water in the present case) when it cuts a normal magnetic field. Large coils buried at the bottom of the channel carry a current I to produce a controlled vertical magnetic field (Fig. 4.18). Electrodes provided at the sides of the channel section measure the small voltage produced due to flow of water in the channel. It has been found that the signal output E will be of the order of millivolts and is related to the discharge Q as n

Ed Q = K1 æ + K2 ö (4.16) è I ø where d = depth of flow, I = current in the coil, and n, K1 and K2 are system constants.

116 Engineering Hydrology

Fig. 4.18 Electromagnetic Method The method involves sophisticated and expensive instrumentation and has been successfully tried in a number of installations. The fact that this kind of set-up gives the total discharge when once it has been calibrated, makes it specially suited for field situations where the cross-sectional properties can change with time due to weed growth, sedimentation, etc. Another specific application is in tidal channels where the flow undergoes rapid changes both in magnitude as well as in direction. Present, day commercially available electromagnetic flowmeters can measure the discharge to an accuracy of ±3%, the maximum channel width that can be accommodated being 100 m. The minimum detectable velocity is 0.005 m/s.

4.7 ULTRASONIC METHOD This is essentially an area-velocity method with the average velocity being measured by using ultrasonic signals. The method was first reported by Swengel (1955), since then it has been perfected and complete systems are available commercially. Consider a channel carrying a flow with two transducers A and B fixed at the same level h above the bed and on either side of the channel (Fig. 4.19). These transducers can receive as well as send ultrasonic signals. Let A send an ultrasonic signal to be received at B after an elapse time t1 Similarly, let B send a signal to be received at A after an elapse time t2. If C = velocity of sound in water, t1 = L/(C + vp) (4.17) where L = length of path from A to B and vp = component of the flow velocity in the sound path = v cos q. Similarly, from Fig. 4.19 it is easy to see that L (4.18) t2 = (C - v p ) Thus

2 v p 2 v cos q 1 1 = = t1 t2 L L

Streamflow Measurement

117

Fig. 4.19 Ultrasonic Method L æ1 1ö (4.19) 2 cos q çè t1 t2 ÷ø Thus for a given L and q, by knowing t1 and t2, the average velocity along the path AB, i.e., v can be determined. It may be noted that v is the average velocity at a height h above the bed and is not the average velocity V for the whole cross-section. However, for a given channel cross-section v can be related to V and by calibration a relation between v/V and h can be obtained. For a given set-up, as the area of cross-section is fixed, the discharge is obtained as a product of area and mean velocity V. Estimation of discharge by using one signal path as above is called single-path gauging. Alternatively, for a given depth of flow, multiple single paths can be used to obtain v for different h values. Mean velocity of flow through the cross-section is obtained by averaging these v values. This techniques is known as multi-path gauging. Ultrasonic flowmeters using the above principal have frequencies of the order of 500 kHz. Sophisticated electronics are involved to transmit, detect and evaluate the mean velocity of flow along the path. In a given installation a calibration (usually performed by the current-meter method) is needed to determine the system constants. Currently available commercial systems have accuracies of about 2% for the singlepath method and 1% for the multipath method. The systems are currently available for rivers up to 500 m width. The specific advantages of the ultrasonic system of river gauging are 1. It is rapid and gives high accuracy. 2. It is suitable for automatic recording of data. 3. It can handle rapid changes in the magnitude and direction of flow, as in tidal rivers. 4. The cost of installation is independent of the size of rivers. The accuracy of this method is limited by the factors that affect the signal velo-city and averaging of flow velocity, such as (i) unstable cross-section, (ii) fluctuating weed growth, (iii) high loads of suspended solids, (iv) air entrainment, and (v) salinity and temperature changes.

or

v=

4.8 INDIRECT METHODS Under this category are included those methods which make use of the relationship between the flow discharge and the depths at specified locations. The field measurement is restricted to the measurements of these depths only.

118 Engineering Hydrology Two broad classifications of these indirect methods are 1. Flow measuring structures, and 2. Slope area method.

Flow-Measuring Structures Use of structures like notches, weirs, flumes and sluice gates for flow measurement in hydraulic laboratories is well known. These conventional structures are used in field conditions also but their use is limited by the ranges of head, debris or sediment load of the stream and the back-water effects produced by the installations. To overcome many of these limitations a wide variety of flow measuring structures with specific advantages are in use. The basic principle governing the use of a weir, flume or similar flow-measuring structure is that these structures produce a unique control section in the flow. At these structures, the discharge Q is a function of the water-surface elevation measured at a specified upstream location, Q = f(H) (4.20) where H = water surface elevation measured from a specified datum. Thus, for example, for weirs, Eq. (4.20) takes the form Q = KHn (4.21) where H = head over the weir and K, n = system constants. Equation (4.20) is applicable so long as the downstream water level is below a certain limiting water level known as the modular limit. Such flows which are independent of the downstream water level are known as free flows. If the tail water conditions do affect the flow, then the flow is known as drowned or submerged flow. Discharges under drowned, condition are obtained by applying a reduction factor to the free flow discharges. For example, the submerged flow over a weir [Fig. 4.20(b)] is estimated by the Villemonte formula, 0.385

é æ H ön ù 2 ú Qs = Q1 ê1 - ç (4.22) êë è H1 ÷ø úû where Qs = submerged discharge, Q1 = free flow discharge under head H1, H1 = upstream water surface elevation measured above the weir crest, H2 = downstream water surface elevation measured above the weir crest, n = exponent of head in the free flow head discharge relationship [Eq. (4.21)]. For a rectangular weir n = 1.5.

Fig. 4.20(a) Flow over a Weir: (a) Free Flow

Streamflow Measurement

119

The various flow measuring structures can be broadly considered under three categories:

Thin-plate structures are usually made

from a vertically set metal plate. The V-notch, rectanFig. 4.20(b) Submerged Flow gular full width and contracted notches are typical examples under this category.

Long-base weirs also known as broad-crested weirs are made of concrete or masonry and are used for large discharge values. Flumes are made of concrete, masonry or metal sheets depending on their use and location. They depend primarily on the width constriction to produce a control section. Details of the discharge characteristics of flow-measuring structures are available in Refs. 1, 2 and 7. Slope-Area Method The resistance equation for uniform flow in an open channel, e.g. Manning’s formula can be used to relate the depths at either ends of a reach to the discharge. Figure 4.21 shows the longitudinal section of the flow in a river between two sections, 1 and 2. KnowFig. 4.21 Slope-area Method ing the water-surface elevations at the two sections, it is required to estimate the discharge. Applying the energy equation to Sections 1 and 2, Z1 + y1 +

V12

= Z2 + y2 +

V22

+ hL 2g 2g where hL = head loss in the reach. The head loss hL can be considered to be made up of two parts (i) frictional loss hf and (ii) eddy loss he. Denoting Z + y = h = watersurface elevation above the datum, V12 V22 = h2 + + he + hf h1 + 2g 2g æ V12 V22 ö or hf = (h1 – h2) + ç (4.23) ÷ – he è2g 2gø

120 Engineering Hydrology If L = length of the reach, by Manning’s formula for uniform flow, hf Q2 = Sf = energy slope = L K2 1 where K = conveyance of the channel = AR 2/3 n In nonuniform flow an average conveyance is used to estimate the average energy slope and hf Q2 = Sf = (4.24) L K2 2/3 2/3 1 1 A1 R1 and K2 = A2 R2 where K = K1 K2 ; K1 = n1 n2 n = Manning’s roughness coefficient The eddy loss he is estimated as he = Ke

V12

-

V22

(4.25)

2g 2g where Ke = eddy-loss coefficient having values as below. Cross-section characteristic of the reach Uniform Gradual transition Abrupt transition

Expansion 0 0.3 0.8

Value of K

Contraction 0 0.1 0.6

Equation (4.23), (4.24) and (4.25) together with the continuity equation Q = A1 V1 = A2 V2 enable the discharge Q to be estimated for known values of h, channel cross-sectional properties and n. The discharge is calculated by a trial and error procedure using the following sequence of calculations 2 2 1. Assume V1 = V2. This leads to V1 /2 g = V2 /2 g and by Eq. (4.23) hf = h1 – h2 = F = fall in the water Surface between Sections 1 and 2 2. Using Eq. (4.24) calculate discharge Q 3. Compute V1 = Q/A1 and V2 = Q/A2. Calculate velocity heads and eddy-loss he 4. Now calculate a refined value of hf by Eq. (4.23) and go to step (2). Repeat the calculations till two successive calculations give values of discharge (or hf) differing by a negligible margin. This method of estimating the discharge is known as the slope-area method. It is a very versatile indirect method of discharge estimation and requires (i) the selection of a reach in which cross-sectional properties including bed elevations are known at its ends, (ii) the value of Manning’s n and (iii) water-surface elevations at the two end sections. EXAMPLE 4.3 During a flood flow the depth of water in a 10 m wide rectangular channel was found to be 3.0 m and 2.9 m at two sections 200 m apart. The drop in the water-surface elevation was found to be 0.12 m. Assuming Manning’s coefficient to be 0.025, estimate the flood discharge through the channel.

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SOLUTION: Using suffixes 1 and 2 to denote the upstream and downstream sections respectively, the cross-sectional properties are calculated as follows: Section 1 y1 A1 P1 R1

Section 2

= 3.0 m = 30 m2 = 16 m = 1.875 m

y2 A2 P2 R2

1 ´ 30 ´ (1.875)2/3 0.025 = 1824.7

= 2.90 m = 29 m2 = 15.8 m = 1.835 m 1 ´ 29 ´ (1.835)2/3 0.025 = 1738.9

KI =

K2 =

Average K for the reach = K1 K 2 = 1781.3 To start with hf = fall = 0.12 m is assumed. Eddy loss he = 0 The calculations are shown in Table 4.1.

S f = hf /L = hf /200

Q=K

Sf

= 1781.3

Sf

2 V22 æ Q ö 2 æQö = ç ÷ /19.62 = çè ÷ø /19.62 , 30 2 g è 29 ø 2g

V12

æ V12 V22 ö hf = (h1 – h2) + ç ÷ è2g 2gø æ V12 V22 ö æ V12 V22 ö hf = fall + ç ÷ = 0.12 + ç ÷ è2g 2gø è2g 2gø

(E–1)

Table 4.1 Calculations for Example 4.3 Trial

1 2 3

V12 / 2 g

V22 / 2 g

hf

(m /s)

(m)

(m)

by Eq. (E–1) (m)

43.63 42.24 42.32

0.1078 0.1010 0.1014

0.1154 0.1081 0.1081

0.1124 0.1129 0.1129

hf

Sf

Q

(trial)

(units of 10-4)

0.1200 0.1124 0.1129

6.000 5.622 5.646

3

(The last column is hf by Eq. (E–1) and its value is adopted for the next trial.) The discharge in the channel is 42.32 m3/s.

Flood Discharge by Slope-Area Method The slope-area method is of particular use in estimating the flood discharges in a river by past records of stages at different sections. Floods leave traces of peak elevations called high-water marks in their wake. Floating vegetative matter, such as grass, straw and seeds are left stranded at high water levels when the flood subsides and form excellent marks. Other highwater marks include silt lines on river banks, trace of erosion on the banks called wash lines and silt or stain lines on buildings. In connection with the estimation of very high

122 Engineering Hydrology floods, interviews with senior citizens living in the area, who can recollect from memory certain salient flood marks are valuable. Old records in archives often provide valuable information on flood marks and dates of occurrence of those floods. Various such information relating to a particular flood are cross-checked for consistency and only reliable data are retained. The slope-area method is then used to estimate the magnitude of the flood. The selection of the reach is probably the most important aspect of the slope-area method. The following criteria can be listed towards this: l The quality of high-water marks must be good. l The reach should be straight and uniform as far as possible. Gradually contracting sections are preferred to an expanding reach. l The recorded fall in the water-surface elevation should be larger than the velocity head. It is preferable if the fall is greater than 0.15 m. l The longer the reach, the greater is the accuracy in the estimated discharge. A length greater than 75 times the mean depth provides an estimate of the reach length required. The Manning’s roughness coefficient n for use in the computation of discharge is obtained from standard tables7. Sometimes a relation between n and the stage is prepared from measured discharges at a neighbouring gauging station and an appropriate value of n selected from it, with extrapolation if necessary.

4.9 STAGE-DISCHARGE RELATIONSHIP As indicated earlier the measurement of discharge by the direct method involves a two step procedure; the development of the stage-discharge relationship which forms the first step is of utmost importance. Once the stage-discharge (G – Q) relationship is established, the subsequent procedure consists of measuring the stage (G) and reading the discharge (Q) from the (G – Q) relationship. This second part is a routine operation. Thus the aim of all current-meter and other direct-discharge measurements is to prepare a stage-discharge relationship for the given channel gauging section. The stagedischarge relationship is also known as the rating curve. The measured value of discharges when plotted against the corresponding stages gives relationship that represents the integrated effect of a wide range of channel and flow parameters. The combined effect of these parameters is termed control. If the (G – Q) relationship for a gauging section is constant and does not change with time, the control is said to be permanent. If it changes with time, it is called shifting control.

Permanent Control A majority of streams and rivers, especially nonalluvial rivers exhibit permanent control. For such a case, the relationship between the stage and the discharge is a singlevalued relation which is expressed as Q = Cr (G – a)b (4.26) in which Q = stream discharge, G = gauge height (stage), a = a constant which represent the gauge reading corresponding to zero discharge, Cr and b are rating curve constants. This relationship can be expressed graphically by plotting the observed relative stage (G – a) against the corresponding discharge values in an arithmetic or logarithmic plot [Fig. 4.22(a) and (b)]. Logarithmic plotting is advantageous as Eq. (4.26) plots as a

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Fig. 4.22(a) Stage-Discharge Curve: Arithmetic Plot

Fig. 4.22(b) Stage-Discharge Curve: Logarithmic Plot straight line in logarithmic coordinates. In Fig. 4.22(b) the straight line is drawn to best represent the data plotted as Q vs (G – a). Coefficients Cr and b need not be the same for the full range of stages. The best values of Cr and b in Eq. (4.26) for a given range of stage are obtained by the least-square-error method. Thus by taking logarithms, log Q = b log (G – a) + log Cr (4.27) or Y = bX + b (4.27a) in which the dependent variable Y = log Q, independent variable X = log (G – a) and b = log Cr. For the best-fit straight line of N observations of X and Y, by regressing X = log (G – a) on Y = log Q N ( SXY ) - ( SX )( SY ) (4.28a) b= N ( SX 2 ) - ( SX ) 2 and

b=

SY - b ( SX )

N Pearson product moment correlation coefficient N ( SXY ) - ( SX )( SY ) r= [ N ( SX 2 ) - ( SX ) 2 ][ N ( SY 2 ) - ( SY )2 ]

(4.28b) (4.29)

124 Engineering Hydrology Here r reflects the extent of linear relationship between the two data sets. For a perfect correlation r = 1.0. If r is between 0.6 and 1.0 it is generally taken as a good correlation. It should be noted that in the present case, as the discharge Q increases with (G – a) the variables Y and X are positively correlated and hence r is positive. Equation (4.26), viz. Q = Cr(G – a)b is called the rating equation of the stream and can be used for estimating the discharge Q of the stream for a given gauge reading G within range of data used in its derivation. Stage for Zero Discharge, a In Eq. (4.26) the constant a representing the stage (gauge height) for zero discharge in the stream is a hypothetical parameter and cannot be measured in the field. As such, its determination poses some difficulties. The following alternative methods are available for its determination: 1. Plot Q vs G on an arithmetic graph paper and draw a best-fit curve. By extrapolating the curve by eye judgment find a as the value of G corresponding to Q = 0. Using the value of a, plot log Q vs log (G – a) and verify whether the data plots as a straight line. If not, select another value in the neighbourhood of previously assumed value and by trial and error find an acceptable value of a which gives a straight line plot of log Q vs log (G – a). 2. A graphical method due to Running8 is as follows. The Q vs G data are plotted to an arithmetic scale and a smooth curve through the plotted points are drawn. Three points A, B and C on the curve are selected such that their discharges are in geometric progression (Fig. Fig. 4.23 Running’s Method for Estimation of the Constant a 4.23), i.e. QB QA = QC QB At A and B vertical lines are drawn and then horizontal lines are drawn at B and C to get D and E as intersection points with the verticals. Two straight lines ED and BA are drawn to intersect at F. The ordinate at F is the required value of a, the gauge height corresponding to zero discharge. This method assumes the lower part of the stage-discharge curve to be a parabola. 3. Plot Q vs G to an arithmetic scale and draw a smooth good-fitting curve by eyejudgement. Select three discharges Q1, Q2 and Q3 such that Q1/Q2 = Q2/Q3 and note from the curve the corresponding values of gauge readings G1, G2 and G3. From Eq. (4.26) (G1 – a)/(G2 – a) = (G2 – a)/(G3 – a) G1 G3 - G22 (4.30) i.e. a= (G + G3 ) - 2 G2

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4. A number of optimization procedures are available to estimate the best value of a. A trial-and-error search for a which gives the best value of the correlation coefficient is one of them. EXAMPLE 4.4 Following are the data of gauge and discharge collected at a particular section of the river by stream gauging operation. (a) Develop a gauge-discharge relationship for this stream at this section for use in estimating the discharge for a known gauge reading. What is the coefficient of correlation of the derived relationship? Use a value of a = 7.50 m for the gauge reading corresponding to zero discharge. (b) Estimate the discharge corresponding to a gauge reading of 10.5 m at this gauging section. Gauge reading (m)

Discharge (m3/s)

Gauge reading (m)

7.65 7.70 7.77 7.80 7.90 7.91 8.08

15 30 57 39 60 100 150

8.48 8.98 9.30 9.50 10.50 11.10 11.70

Discharge (m3/s) 170 400 600 800 1500 2000 2400

SOLUTION: (a) The gauge–discharge equation is Q = Cr(G – a)b

Taking the logarithms log Q = b log (G – a) + log Cr or Y = bX + b where Y = log Q and X = log (G – a). Values of X, Y and XY are calculated for all the data as shown in Table 4.2.

Table 4.2 Calculations for Example 4.4 a = 7.5 m N = 14 Stage (G) (G – a) (metres) (m) 7.65 7.70 7.77 7.80 7.90 7.91 8.08 8.48 8.98 9.30 9.50 10.50 11.10 11.70

0.15 0.20 0.27 0.30 0.40 0.41 0.58 0.98 1.48 1.80 2.00 3.00 3.60 4.20

Discharge (Q)(m3/s) 15 30 57 39 60 100 150 170 400 600 800 1500 2000 2400 Sum

log (G – a) =X

log Q =Y

XY

X2

Y2

–0.824 –0.699 –0.569 –0.523 –0.398 –0.387 –0.237 –0.009 0.170 0.255 0.301 0.477 0.556 0.623 –1.262

1.176 1.477 1.756 1.591 1. 778 2.000 2.176 2.230 2.602 2.778 2.903 3.176 3.301 3.380 32.325

–0.969 –1.032 –0.998 –0.832 –0.708 –0.774 –0.515 –0.020 0.443 0.709 0.874 1.515 1.836 2.107 1.636

0.679 0.489 0.323 0.273 0.158 0.150 0.056 0.000 0.029 0.065 0.091 0.228 0.309 0.388 3.239

1.383 2.182 3.083 2.531 3.162 4.000 4.735 4.975 6.771 7.718 8.428 10.088 10.897 11.426 81.379

126 Engineering Hydrology From the above table: SX = –1.262 SY = 32.325 SXY = 1.636 SX2 = 3.239 SY2 = 81.379 (SX)2 = 1.5926 (SY)2 = 1044.906 N = 14 By using Eq. (4.28a) N ( SXY ) - ( SX )( SY ) (14 ´ 1.636) - ( -1.262)(32.325) b= = = 1.4558 2 2 (14 ´ 3.239) - ( -1.262)2 N ( SX ) - ( SX ) By Eq. (4.28b) SY - b ( SX ) (32.325) - 1.4558 ´ ( -1.262) b= = = 2.440 N 14 Hence Cr = 275.52 The required gauge–discharge relationship is therefore Q = 275.52 (G – a)1.456 By Eq. 4.29 coefficient of correlation N ( SXY ) - ( SX )( SY ) r= [ N ( SX 2 ) - ( SX ) 2 ][ N ( SY 2 ) - ( SY ) 2 ] =

(14 ´ 1.636) - ( -1.262)(32.325)

= 0.9913 [(14 ´ 3.239) - (1.5926)][(14 ´ 81.379) - (1044.906)] As the value of r is nearer to unity the correlation is very good. The variation of discharge (Q) with relative stage (G – a) is shown in Fig. 4.24(a)— arithmetic plot and in Fig. 4.24(b)—logarithmic plot. (b) when G = 10.05: as a = 7.5 m G = 275.52 (10.05 – 7.50)1.456 = 1076 m3/s

Fig. 4.24(a) Stage-discharge Relation (Arithmetic Plot)—Example 4.4

Shifting Control The control that exists at a gauging section giving rise to a unique stage-discharge relationship can change due to: (i) changing characteristics caused by weed growth,

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Fig. 4.24(b) Stage-discharge Relationship (Logarithmic Plot)—Example 4.4 dredging or channel encroachment, (ii) aggradation or degradation phenomenon in an alluvial channel, (iii) variable backwater effects affecting the gauging section and (iv) unsteady flow effects of a rapidly changing stage. There are no permanent corrective measure to tackle the shifting controls due to causes (i) and (ii) listed above. The only recourse in such cases is to have frequent current-meter gaugings and to update the rating curves. Shifting controls due to causes (iii) and (iv) are described below. Backwater Effect If the shifting control is due to variable backwater curves, the same stage will indicate different discharges depending upon the backwater effect. To remedy this situation another gauge, called the secondary gauge or auxiliary gauge is installed some distance downstream of the gauging section and readings of both gauges are taken. The difference between the main gauge and the secondary gauge gives the fall (F) of the water surface in the reach. Now, for a given main-stage reading, the discharge under variable backwater condition is a function of the fall F, i.e. Q = f(G, F) Schematically, this functional relationship is shown in Fig. 4.25. Instead of having a three-parameter plot, the observed data is normalized with respect to a constant fall value. Let F0 be a normalizing value of the fall taken to be constant at all stages and F the actual fall at a given stage when the actual discharge is Q. These two fall values are related as m Q æ Fö = ç ÷ (4.31) Q0 è F0 ø in which Q0 = normalized discharge at the given stage when the fall is equal to F0 and m = an

Fig. 4.25

Backwater Effect on a Rating Curve—Normalised Curve

128 Engineering Hydrology exponent with a value close to 0.5. From the observed data, a convenient value of F0 is selected. An approximate Q0 vs G curve for a constant F0 called constant fall curve is drawn. For each observed data, Q/Q0 and F/F0 values are calculated and plotted as Q/Q 0 vs F/F 0 (Fig. 4.26). This is called the adjustment curve. Both the constant fall curve and the adjustment curve are refined, by trial and error to get the Fig. 4.26 Backwater Effect on a Rating Curve— best-fit curves. When finalAdjustment Curve ized, these two curves provide the stage-discharge information for gauging purposes. For example, if the observed stage is G1 and fall F1, first by using the adjustment curve the value of Q1/Q0 is read for a known value of F1/F0. Using the constant fall-rating curve, Q0 is read for the given stage G1 and the actual discharge calculated as (Q1/Q0) ´ Q0. Unsteady-Flow Effect When a flood wave passes a gauging station in the advancing portion of the wave the approach velocities are larger than in the steady flow at corresponding stage. Thus for the same stage, more-discharge than in a steady uniform flow occurs. In the retreating phase of the flood wave the converse situation occurs with reduced approach velocities giving lower discharges than in an equivalent steady flow case. Thus the stage-discharge relationship for an unsteady flow will not be a single-valued relationship as in steady flow but it will be a looped curve as in Fig. 4.27. It may be noted that at the same stage, more discharge passes through the river during rising stages than in falling ones. Since the conditions for each flood may be different, different floods may Fig. 4.27 Loop Rating Curve give different loops. If Qn is the normal discharge at a given stage under steady uniform flow and QM is the measured (actual) unsteady flow the two are related as7 QM 1 dh = 1+ (4.32) Qn Vw S0 dt where S0 = channel slope = water surface slope at uniform flow, dh/dt = rate of change of stage and Vw = velocity of the flood wave. For natural channels, Vw is usually

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assumed equal to 1.4 V, where V = average velocity for a given stage estimated by applying Manning’s formula and the energy slope S f . Also, the energy slope is used in place of S0 in the denominator of Eq. (4.32). If enough field data about the flood magnitude and dh/dt are available, the term (1/Vw S0) can be calculated and plotted against the stage for use in Eq. (4.32). For estimating the actual discharge at an observed stage, QM/Qn is calculated by using the observed data of dh/ dt. Here Qn is the discharge corresponding to the observed stage relationship for steady flow in the channel reach. EXAMPLE 4.5 An auxiliary gauge was used downstream of a main gauge in a river to provide corrections to the gauge-discharge relationship due to backwater effects. The following data were noted at a certain main gauge reading. Main gauge (m above datum)

Auxiliary gauge (m above datum)

Discharge (m3/s)

86.00 86.00

85.50 84 80

275 600

If the main gauge reading is still 86.00 m and the auxiliary gauge reads 85.30 m, estimate the discharge in the river.

SOLUTION: Fall (F) = main gauge reading – auxiliary gauge reading.

F1 = (86.00 – 85.50) = 0.50 m Q1 = 275 m3/s F2 = (86.00 – 84.80) = 1.20 m Q2 = 600 m3/s By Eq. (4.31) (Q1/Q2) = (F1/F2)m or (275/600) = (0.50/1.20)m Hence m = 0.891 When the auxiliary gauge reads 85.30 m, at a main gauge reading of 86.00 m, Fall F = (86.00 – 85.30) = 0.70 m and Q = Q2 (F/F2)m = 600 (0.70/1.20)0.891 = 371 m3/s When

4.10 EXTRAPOLATION OF RATING CURVE Most hydrological designs consider extreme flood flows. As an example, in the design of hydraulic structures, such as barrages, dams and bridges one needs maximum flood discharges as well as maximum flood levels. While the design flood discharge magnitude can be estimated from other considerations, the stage-discharge relationship at the project site will have to be used to predict the stage corresponding to design-flood discharges. Rarely will the available stage-discharge data include the design-flood range and hence the need for extrapolation of the rating curve. Before attempting extrapolation, it is necessary to examine the site and collect relevant data on changes in the river cross-section due to flood plains, roughness and backwater effects. The reliability of the extrapolated value depends on the stability of the gauging section control. A stable control at all stages leads to reliable results. Extrapolation of the rating curve in an alluvial river subjected to aggradation and degradation is unreliable and the results should always be confirmed by alternate methods. There are many techniques of extending the rating curve and two well-known methods are described here.

130 Engineering Hydrology

Conveyance Method The conveyance of a channel in nonuniform flow is defined by the relation Q = K Sf (4.33) where Q = discharge in the channel, Sf = slope of the energy line and K = conveyance. If Manning’s formula is used, 1 K = AR 2/3 (4.34) n where n = Manning’s roughness, A = area of cross-section and, R = hydraulic radius. Since A and R are functions of the stage, the values of K for various values of stage are calculated by using Eq. (4.34) and plotted against the stage. The range of the stage should include values beyond the level up to which extrapolation is desired. Then a smooth curve is fitted to the plotted points as shown in Fig. 4.28(a). Using the available discharge and stage data, values of Sf are calculated by using Eq. (4.33) as Sf = Q2/K2 and are plotted against the stage. A smooth curve is fitted through the plotted points as shown in Fig. 4.28(b). This curve is then extrapolated keeping in mind that Sf approaches a constant value at high stages.

Fig. 4.28(a)

Conveyance Method of Rating Curve Extension: K vs Stage

Fig. 4.28(b)

Conveyance Method of Rating Curve Extension: Sf vs Stage

Using the conveyance and slope curves, the discharge at any stage is calculated as Q = K S f and a stage-discharge curve covering the desired range of extrapolation is constructed. With this extrapolated-rating curve, the stage corresponding to a designflood discharge can be obtained.

Logarithmic-Plot Method In this technique the stage-discharge relationship given by Eq. (4.26) is made use of. The stage is plotted against the discharge on a log–log paper. A best-fit linear relationship is obtained for data points lying in the high-stage range and the line is extended to cover the range of extrapolation. Alternatively, coefficients of Eq. (4.26) are obtained by the least-square-error method by regressing X on Y in Eq. (4.27a). For this Eq. (4.27a) is written as

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X = aY + C (4.35) where the dependent variable X = log (G – a) and Y = log Q. The coefficients a and C are obtained as, N ( SXY ) - ( SY )( SX ) a= (4.35a) N ( SY 2 ) - ( SY ) 2 and

C=

( SX ) - a ( SY )

(4.35b) N The relationship governing the stage and discharge is now (4.36) (G – a) = C1Qa where C1 = antilog C. By the use of Eq. (4.36) the value of the stage corresponding to a design flood discharge is estimated. EXAMPLE 4.6 For the stage-discharge data of Example 4.4, fit a regression equation for use in estimation of stage for a known value of discharge. Use a value of 7.50 m as the gauge reading corresponding to zero discharge. Determine the stage for a discharge of 3500 m3/s. SOLUTION: The regression equation is X = aY + C

(Eq. 4.35) where X = log(G – a) and Y = log Q. The value of a is given by Eq. (4.35a) as N ( SXY ) - ( SY )( SX ) a= N ( SY 2 ) - ( S Y ) 2 Values of X, Y and XY are the same as calculated for the data in Table 4.3. Thus SX = –1.262 SY = 32.325 SXY = 1.636 SX2 = 3.239 SY2 = 81.379 (SX)2 = 1.5926 (SY)2 = 1044.906 N = 14 Substituting these values in Eq. (4.35) (14 ´ 1.636) - (32.325)( -1.262) a= = 0.675 (14 ´ 81.379) - (1044.906) The coefficient C is given by Eq. (4.35b) as ( SX ) - a ( SY ) ( -1.262) - 0.675 (32.325) = = –1.6486 C= N 14 C1 = antilog C = 0.02246 leading to the gage-discharge equation as (G – a) = 0.02246 Q0.675 The variation of relative stage (G – a) with discharge (Q) is shown in Fig. 4.29(a)— arithmetic plot and in Fig. 4.29(b)—logarithmic plot. (b) When Q = 3500 m3/s and given that a = 7.50 m (G – 7.50) = 0.02246 (3500)0.675 = 5.540 m G = 13.04 m

4.11 HYDROMETRY STATIONS As the measurement of discharge is of paramount importance in applied hydrologic studies, considerable expenditure and effort are being expended in every country to collect and store this valuable historic data. The WMO recommendations for the minimum number of hydrometry stations in various geographical regions are given in Table 4.3.

132 Engineering Hydrology

Fig. 4.29(a) Discharge-stage Relationship: Example 4.6 (Logarithmic Plot)

Fig. 4.29(b) Discharge-stage Relationship: Example 4.6 (Arithmetic Plot) Table 4.3 WMO Criteria for Hydrometry Station Density S. No.

1. 2. 3.

Region

Minimum density (km2/station)

Flat region of temperate, 1,000 – 2,500 mediterranean and tropical zones Mountainous regions of temperate 300 – 1,000 mediterranean and tropical zones Arid and polar zones 5,000 – 20,000

Tolerable density under difficult conditions (km2/station) 3,000 – 10,000 1,000 –

5,000

Hydrometry stations must be sited in adequate number in the catchment area of all major streams so that the water potential of an area can be assessed as accurately as possible.

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As a part of hydrological observation activities CWC operates a vast network of 877 hydrological observation stations on various state and interstate rivers for collection of gauge, discharge, silt and water quality data which are stored after analysis in central data bank. In addition to observation of river flow, CWC is also monitoring water quality, covering all the major river basins of India. The distribution of various kinds of CWC hydrological observation stations is as follows: Type of Station

Number

Gauge observation only Gauge—Discharge Gauge—Discharge and Silt Gauge—Discharge and water quality Gauge—Discharge, water quality and Silt

236 281 41 80 239

In a few gauging stations on major rivers, moving boat method facilities exist. Reports containing the gauge, discharge, sediment and water quality data are brought out by CWC every year as Year books. In addition to the above, the state governments maintain nearly 800 gauging stations. Further, in most of the states institutional arrangements exist for collection, processing and analysis of hydrometric and hydrometeorological data and publication of the same.

REFERENCES 1. Ackers, P. et al., Weirs and Flumes for Flow Measurement, Wiley Interscience, John Wiley, Chichester, U.K., 1978. 2. Bos, M.G. (Ed.), Discharge Measuring Structures, Int. Inst. for Land Reclamation and Improvement, Wageningen, The Netherlands, Pb. No. 20, 1976. 3. Central Water Commission, Water Resources of India, CWC Pub. No. 30/88, CWC, New Delhi, India, 1988. 4. Chow, V.T. (Ed.), Handbook of Applied Hydrology, McGraw-Hill, New York, USA, 1964. 5. Hershey, R.W. (Ed.), Hydrometry, Wiley Interscience, John Wiley, Chichester, U.K., 1978. 6. Kolupaila, S., Bioliography of Hydrometry, Univ. of Notre Dame, Notre Dame, USA, 1960. 7. Subramanya, K., Flow in Open Channels, 2 ed. Tata McGraw-Hill, New Delhi, India, 1997. 8. Wisler, C.O., and E.F. Brater, Hydrology, John Wiley, New York, USA, 1959.

REVISION QUESTIONS 4.1 Explain the various commonly used methods of measurement of stage of a river. Indicate for each method its specific advantage and the conditions under which one would use it. 4.2 What factors should be considered in selecting a site for a stream gauging station? 4.3 Explain the salient features of a current meter. Describe briefly the procedure of using a current meter for measuring velocity in a stream. 4.4 List the qualities of a good tracer for use in dilution technique of flow measurement. 4.5 Explain briefly the dilution method of flow measurement. 4.6 Explain the streamflow measurement by area-velocity method. 4.7 Describe briefly the moving boat method of stream flow measurement. 4.8 Describe the slope-area method of measurement of flood discharge in a stream. 4.9 Explain the procedure for obtaining the stage-discharge relationship of a stream by using the stage-discharge data from a site with permanent control.

134 Engineering Hydrology 4.10 Describe briefly: (a) Backwater effect on a rating curve. (b) Unsteady flow effect on a rating curve 4.11 Describe a procedure for extrapolating a rating curve of a stream. 4.12 Discuss the advantages and disadvantages of the following relative to the flow measurement by using current meters: (a) Electromagnetic method (b) Ultrasound method 4.13 Explain briefly the important aspects relating to the following instruments (a) Float-gauge recorder (b) Bubble gauge (c) Echo-depth recorder (d) Current meter

PROBLEMS 4.1 The following data were collected during a stream-gauging operation in a river. Compute the discharge. Distance from left water edge (m)

Depth (m)

0.0 1.5 3.0 4.5 6.0 7.5 9.0

0.0 1.3 2.5 1.7 1.0 0.4 0.0

Velocity (m/s) at 0.2 d

at 0.8 d

0.0 0.6 0.9 0.7 0.6 0.4 0.0

0.0 0.4 0.6 0.5 0.4 0.3 0.0

4.2 The velocity distribution in a stream is usually approximated as v/va = (y/a)m, where v and va are velocities at heights y and a above the bed respectively and m is a coefficient with a value between 1/5 to 1/8. (i) Obtain an expression for v / v , where v is the mean velocity in terms of the depth of flow. (ii) If m = 1/6 show that (a) the measured velocity is equal to the mean velocity if the velocity is measured at 0.6 depth from the water 1 surface and (b) v = (v0.2 + v0.82), where v0.2 and v0.82 are the velocities measured at 0.2 2 and 0.82 depths below the water surface respectively. 4.3 The following are the data obtained in a stream-gauging operation. A current meter with a calibration equation V = (0.32N + 0.032) m/s, where N = revolutions per second was used to measure the velocity at 0.6 depth. Using the mid-section method, calculate the discharge in the stream. Distance from right bank (m) Depth (m) Number of revolutions Observation Time (s)

0 0

2 4 6 9 12 15 18 20 22 23 24 0.50 1.10 1.95 2.25 1.85 1.75 1.65 1.50 1.25 0.75 0

80

83

131 139 121 114 109

92

85

70

180 120 120 120 120 120 120 120 120 150

4.4 In the moving-boat method of discharge measurement the magnitude (VR) and direction (q) of the velocity of the stream relative to the moving boat are measured. The depth of the stream is also simultaneously recorded. Estimate the discharge in a river that gave the following moving-boat data. Assume the mean velocity in a vertical to be 0.95 times the surface velocity measured by the instrument.

Streamflow Measurement

4.5

Section

VR (m/s)

q (degrees)

Depth (m)

0 1 2 3 4 5 6 7 8 9 10

— 1.75 1.84 2.00 2.28 2.30 2.20 2.00 1.84 1.70 —

— 55 57 60 64 65 63 60 57 54 —

— 1.8 2.5 3.5 3.8 4.0 3.8 3.0 2.5 2.0 —

4.7

4.8

4.9

Remark Right bank. q is the angle made by VR with the boat direction The various sections are spaced at a constant distance of 75 m apart Left bank

The dilution method with the sudden-injection procedure was used to measure the discharge of a stream. The data of concentration measurements are given below. A fluorescent dye weighing 300 N used as a tracer was suddenly injected at station A at 07 h. Time (h) Concentration at station B in parts per 109 by weight

4.6

135

07 üï ý 0 ïþ

08

09

10

11

12

13

14

15

16

17

18

3.0 10.5 18.0 18.0 12.0 9.0

6.0

4.5

1.5

Estimate the stream discharge. A 500 g/l solution of sodium dichromate was used as chemical tracer. It was dosed at a constant rate of 4 l/s and at a downstream section. The equilibrium concentration was, measured as 4 parts per million (ppm). Estimate the discharge in the stream. A 200 g/l solution of common salt was discharged into a stream at a constant rate of 25 l/s. The background concentration of the salt in the stream water was found to be 10 ppm. At a downstream section where the solution was believed to have been completely mixed, the salt concentration was found to reach an equilibrium value of 45 ppm. Estimate the discharge in the stream. It is proposed to adopt the dilution method of stream gauging for a river whose hydraulic properties at average flow are as follows: width = 45 m, depth = 2.0 m, discharge = 85 m3/s, Chezy coefficient = 20 to 30. Determine the safe mixing length that has to be adopted for this stream. During a high flow water-surface elevations of a small stream were noted at two sections A and B, 10 km apart. These elevations and other salient hydraulic properties are given below. Section

Water-surface elevation (m)

Area of cross-section (m2)

Hydraulic radius (m)

Remarks

A B

104.771 104.500

73.293 93.375

2.733 3.089

A is upsteam of B n = 0.020

The eddy loss coefficients of 0.3 for gradual expansion and 0.1 for gradual contraction are appropriate. Estimate the discharge in the stream. 4.10 A small stream has a trapezoidal cross section with base width of 12 m and side slope 2 horizontal: 1 vertical in a reach of 8 km. During a flood the high water levels record at the ends of the reach are as follows.

136 Engineering Hydrology Section

Elevation of bed (m)

Water surface elevation (m)

Remarks

100.20 98.60

102.70 101.30

Manning’s n = 0.030

Upstream Downstream

Estimate the discharge in the stream. 4.11 The stage-discharge data of a river are given below. Establish the stage-discharge relationship to predict the discharge for a given stage. Assume the value of stage for zero discharge as 35.00 m. (2) What is the correlation coefficient of the relationship established above? (3) Estimate the discharge corresponding to stage values of 42.50 m and 48.50 m respectively. Stage (m)

Discharge (m3/s)

Stage (m)

Discharge (m3/s)

35.91 36.90 37.92 44.40 45.40 46.43

89 230 360 3800 4560 5305

39.07 41.00 43.53 48.02 49.05 49.55 49.68

469 798 2800 5900 6800 6900 6950

4.12 Downstream of a main gauging station, an auxiliary gauge was installed and the following readings were obtained. Main gauge (m)

Auxiliary gauge (m)

Discharge (m3/s)

121.00 121.00

120.50 119.50

300 580

What discharge is indicated when the main gauge reading is 121.00 m and the auxiliary gauge reads 120.10 m. 4.13 The following are the coordinates of a smooth curve drawn to best represent the stagedischarge data of a river. Stage (m) Discharge (m3/s)

20.80 100

21.42 200

21.95 300

23.37 400

23.00 600

23.52 800

23.90 1000

Determine the stage corresponding to zero discharge. 4.14 The stage discharge data of a river are given below. Establish a stage-discharge relationship to predict the stage for a known discharge. Assume the stage value for zero discharge as 20.50 m. Determine the stage of the river corresponding to a discharge of 2600 m3/s. Stage (m)

Discharge (m3/s)

Stage (m)

Discharge (m3/s)

21.95 22.45 22.80 23.00 23.40 23.75 23.65

100 220 295 400 490 500 640

24.05 24.55 24.85 25.40 25.15 25.55 25.90

780 1010 1220 1300 1420 1550 1760

(Hint: Use Eq. 4.35)

Streamflow Measurement

137

4.15 During a flood the water surface at a section in a river was found to increase at a rate of 11.2 cm/h. The slope of the river is 1/3600 and the normal discharge for the river stage read from a steady-flow rating curve was 160 m3/s . If the velocity of the flood wave can be assumed as 2.0 m/s, determine the actual discharge.

OBJECTIVE QUESTIONS 4.1

The science and practice of water flow measurement is known as (a) Hypsometry (b) Hydro-meteorology (c) Fluvimetry (d) Hydrometry 4.2 The following is not a direct stream flow determination technique (a) Dilution method (b) Ultrasonic method (c) Area-velocity method (d) Slope-area method 4.3 A stilling well is required when the stage measurement is made by employing a (a) bubble gauge (b) float gauge recorder (c) vertical staff gauge (d) inclined staff gauge 4.4 In a river carrying a discharge of 142 m3/s, the stage at a station A was 3.6 m and the water surface slope was 1 in 6000. If during a flood the stage at A was 3.6 m and the water surface slope was 1/3000, the flood discharge (in m3/s) was approximately (a) 100 (b) 284 (c) 71 (d) 200 4.5 In a triangular channel the top width and depth of flow were 2.0 m and 0.9 m respectively. Velocity measurements on the centre line at 18 cm and 72 cm below water surface indicated velocities of 0.60 m/s and 0.40 m/s respectively. The discharge in the channel (in m3/s) is (a) 0.90 (b) 1.80 (c) 0.45 (d) none of these. 4.6 In the moving-boat method of stream-flow measurement, the essential measurements are: (a) the velocity recorded by the current meter, the depths and the speed of the boat. (b) the velocity and direction of the current meter, the depths and the time interval between depth readings (c) the depth, time interval between readings, speed of the boat and velocity of the stream (d) the velocity and direction of the current meter and the speed of the boat. 4.7 Which of the following instruments in not connected with stream flow measurement (a) hygrometer (b) Echo-depth recorder (c) Electro-magnetic flow meter (d) Sounding weight 4.8 The surface velocity at any vertical section of a stream is (a) not of any use in stream flow measurement (b) smaller than the mean velocity in that vertical (c) larger than the mean velocity in that vertical section (d) equal to the velocity in that vertical at 0.6 times the depth. 4.9 If a gauging section is having shifting control due to backwater effects, then (a) a loop rating curve results (b) the section is useless for stream-gauging purposes (c) the discharge is determined by area-velocity methods (d) a secondary gauge downstream of the section is needed. 4.10 The stage discharge relation in a river during the passage of a flood wave is measured. If QR = discharge at a stage when the water surface was rising and QF = discharge at the same stage when the water surface was falling, then (a) QF = QR (b) QR > QF (c) QR < QF (d) QR/QF = constant at all stages

138 Engineering Hydrology 4.11 A large irrigation canal can be approximated as a wide rectangular channel and Manning’s formula is applicable to describe the flow in it. If the gauge (G) is related to discharge (Q) as Q = Cr(G – a)b where a = gauge height at zero discharge, the value of b is (a) 1.67 (b) 1.50 (c) 2.50 (d) 0.67 4.12 The dilution method of stream gauging is ideally suited for measuring discharges in (a) a large alluvial river (b) flood flow in a mountain stream (c) steady flow in a small turbulent stream (d) a stretch of a river having heavy industrial pollution loads. 4.13 A 400 g/l solution of common salt was discharged into a stream at a constant rate of 45 l/s. At a downstream section where the salt solution is known to have completely mixed with the stream flow the equilibrium concentration was read as 120 ppm. If a background concentration of 20 ppm is applicable, the discharge in the stream can be estimated to be, in m3/s, as (a) 150 (b) 180 (c) 117 (d) 889 4.14 In the gulp method of stream gauging by dilution technique, 60 litres of chemical X with concentration of 250 g/litre is introduced suddenly in to the stream at a section. At a downstream monitoring section the concentration profile of chemical X that crossed the section was found to be a triangle with a base of 10 hours and a peak of 0.10 ppm. The discharge in the stream can be estimated to be about (a) 83 m3/s (b) 180 m3/s (c) 15000 m3/s (d) 833 m3/s 4.15 The slope-area method is extensively used in (a) development of rating curve (b) estimation of flood discharge based on high-water marks (c) cases where shifting control exists. (d) cases where backwater effect is present. 4.16 For a given stream the rating curve applicable to a section is available. To determine the discharge in this stream, the following-data are needed (a) current meter readings at various verticals at the section (b) slope of the water surface at the section (c) stage at the section (d) surface velocity at various sections. 4.17 During a flood in a wide rectangular channel it is found that at a section the depth of flow increases by 50% and at this depth the water-surface slope is half its original value in a given interval of time. This marks an approximate change in the discharge of (a) –33% (b) +39% (c) +20% (d) no change. 4.18 In a river the discharge was 173 m3/s, the water surface slope was 1 in 6000 and the stage at the station X was 10.00 m. If during a flood, the stage at station X was 10.00 and the water surface slope was 1/2000, the flood discharge was approximately (a) 100 m3/s (b) 519 m3/s (c) 300 m3/s (d) 371 m3/s 4.19 During a flood, the water surface at a section was found to decrease at a rate of 10 cm/h. The slope of the river is 1/3600. Assuming the velocity of the flood wave as 2 m/s, the actual discharge in the stream can be estimated as (a) 2.5% larger than the normal discharge (b) 5% smaller than the normal discharge (c) 2.5% smaller than the normal discharge (d) Same as the normal discharge where normal discharge is the discharge at a given stage under steady, uniform flow.

Chapter

5

RUNOFF

5.1 INTRODUCTION Runoff means the draining or flowing off of precipitation from a catchment area through a surface channel. It thus represents the output from the catchment in a given unit of time. Consider a catchment area receiving precipitation. For a given precipitation, the evapotranspiration, initial loss, infiltration and detention storage requirements will have to be first satisfied before the commencement of runoff. When these are satisfied, the excess precipitation moves over the land surfaces to reach smaller channels. This portion of the runoff is called overland flow and involves building up of a storage over the surface and draining off of the same. Usually the lengths and depths of overland flow are small and the flow is in the laminar regime. Flows from several small channels join bigger channels and flows from these in turn combine to form a larger stream, and so on, till the flow reaches the catchment outlet. The flow in this mode, where it travels all the time over the surface as overland flow and through the channels as open-channel flow and reaches the catchment outlet is called surface runoff. A part of the precipitation that infilters moves laterally through upper crusts of the soil and returns to the surface at some location away from the point of entry into the soil. This component of runoff is known variously as interflow, through flow, storm seepage, subsurface storm flow or quick return flow (Fig. 5.1). The amount of interflow

Fig. 5.1 Different routes of runoff

140 Engineering Hydrology depends on the geological conditions of the catchment. A fairly pervious soil overlying a hard impermeable surface is conducive to large interflows. Depending upon the time delay between the infiltration and the outflow, the interflow is sometimes classified into prompt interflow, i.e. the interflow with the least time lag and delayed interflow. Another route for the infiltered water is to undergo deep percolation and reach the groundwater storage in the soil. The groundwater follows a complicated and long path of travel and ultimately reaches the surface. The time lag, i.e. the difference in time between the entry into the soil and outflows from it is very large, being of the order of months and years. This part of runoff is called groundwater runoff or groundwater flow. Groundwater flow provides the dry-weather flow in perennial streams. Based on the time delay between the precipitation and the runoff, the runoff is classified into two categories; as 1. Direct runoff, and 2. Base flow. These are discussed below.

Direct Runoff It is that part of the runoff which enters the stream immediately after the rainfall. It includes surface runoff, prompt interflow and rainfall on the surface of the stream. In the case of snow-melt, the resulting flow entering the stream is also a direct runoff. Sometimes terms such as direct storm runoff and storm runoff are used to designate direct runoff. Direct runoff hydrographs are studied in detail in Chapter 6.

Base Flow The delayed flow that reaches a stream essentially as groundwater flow is called base flow. Many times delayed interflow is also included under this category. In the annual hydrograph of a perennial stream (Fig. 5.2) the base flow is easily recognized as the slowly decreasing flow of the stream in rainless periods. Aspects relating to the identification of base flow in a hydrograph are discussed in Chapter 6.

Natural Flow Runoff representing the response of a catchment to precipitation reflects the integrated effects of a wide range of catchment, climate and rainfall characteristics. True runoff is therefore stream flow in its natural condition, i.e. without human intervention. Such a stream flow unaffected by works of man, such as reservoirs and diversion structures on a stream, is called natural flow or virgin flow. When there exists storage or diversion works on a stream, the flow on the downstream channel is affected by the operational and hydraulic characteristics of these structures and hence does not represent the true runoff, unless corrected for the diversion of flow and return flow. The natural flow (virgin flow) volume in time D t at the terminal point of a catchment is expressed by water balance equation as RN = (Ro – Vr) + Vd + E + EX + D S (5.1) where RN = Natural flow volume in time D t Ro = Observed flow volume in time D t at the terminal site Vr = Volume of return flow from irrigation, domestic water supply and industrial use Vd = Volume diverted out of the stream for irrigation, domestic water supply and industrial use

Runoff

141

E = net evaporation losses from reservoirs on the stream EX = Net export of water from the basin DS = Change in the storage volumes of water storage bodies on the stream In hydrological studies, one develops relations for natural flows. However, natural flows have to be derived based on observed flows and data on abstractions from the stream. In practice, however, the observed stream flow at a site includes return flow and is influenced by upstream abstractions. As such, natural flows have to be derived based on observed flows and data on abstractions from the stream. Always, it is the natural flow that is used in all hydrological correlations. Example 5.1 explains these aspects clearly. EXAMPLE 5.1 The following table gives values of measured discharges at a stream– gauging site in a year. Upstream of the gauging site a weir built across the stream diverts 3.0 Mm3 and 0.50 Mm3 of water per month for irrigation and for use in an industry respectively. The return flows from the irrigation is estimated as 0.8 Mm3 and from the industry at 0.30 Mm3 reaching the stream upstream of the gauging site. Estimate the natural flow. If the catchment area is 180 km2 and the average annual rainfall is 185 cm, determine the runoff-rainfall ratio. Month Gauged flow (Mm3)

1 2 3 4 5 6 7 8 9 10 11 12 2.0 1.5 0.8 0.6 2.1 8.0 18.0 22.0 14.0 9.0 7.0 3.0

SOLUTION: In a month the natural flow volume RN is obtained from Eq. (5.1) as RN = (Ro – Vr) + Vd + E + EX + DS Here E, EX and DS are assumed to be insignificant and of zero value. Vr = Volume of return flow from irrigation, domestic water supply and industrial use = 0.80 + 0.30 = 1.10 Mm3 Vd = Volume diverted out of the stream for irrigation, domestic water supply and industrial use = 3.0 + 0.5 = 3.5 Mm3 The calculations are shown in the following Table: Month 3

Ro(Mm ) Vd(Mm3) Vr(Mm3) RN(Mm3)

1

2

3

4

5

2.0 3.5 1.1 4.4

1.5 3.5 1.1 3.9

0.8 3.5 1.1 3.2

0.6 3.5 1.1 3.0

2.1 3.5 1.1 4.5

6

7

8

9

10

8.0 18.0 22.0 14.0 9.0 3.5 3.5 3.5 3.5 3.5 1.1 1.1 1.1 1.1 1.1 10.4 20.4 24.4 16.4 11.4

11

12

7.0 3.5 1.1 9.4

3.0 3.5 1.1 5.4

Total RN = 116.8 Mm3 Annual natural flow volume = Annual runoff volume = 116.8 Mm3 Area of the catchment = 180 km2 = 1.80 ´ 108 1.168 ´ 108 Annual runoff depth = = 0.649 m = 64.9 cm 1.80 ´ 108 Annual rainfall = 185 cm (Runoff/Rainfall) = 64.9/185 = 0.35

5.2

HYDROGRAPH

A plot of the discharge in a stream plotted against time chronologically is called a hydrograph. Depending upon the unit of time involved, we have

142 Engineering Hydrology Annual hydrographs showing the variation of daily or weekly or 10 daily mean flows over a year. l Monthly hydrographs showing the variation of daily mean flows over a month. l Seasonal hydrographs depicting the variation of the discharge in a particular season such as the monsoon season or dry season. l Flood hydrographs or hydrographs due to a storm representing stream flow due to a storm over a catchment. Each of these types have particular applications. Annual and seasonal hydrographs are of use in (i) calculating the surface water potential of stream, (ii) reservoir studies, and (iii) drought studies. Flood hydrographs are essential in analysing stream characteristics associated with floods. This chapter is concerned with the estimation and use of long-term runoffs. The study of storm hydrograph forms the subject matter of the next chapter. l

Water Year In annual runoff studies it is advantageous to consider a water year beginning from the time when the precipitation exceeds the average evapotranspiration losses. In India, June 1st is the beginning of a water year which ends on May 31st of the following calendar year. In a water year a complete cycle of climatic changes is expected and hence the water budget will have the least amount of carryover.

5.3 RUNOFF CHARACTERISTICS OF STREAMS A study of the annual hydrographs of streams enables one to classify streams into three classes as (i) perennial, (ii) intermittent and (iii) ephemeral. A perennial stream is one which always carries some flow (Fig. 5.2). There is considerable amount of groundwater flow throughout the year. Fig. 5.2 Perennial stream Even during the dry seasons the water table will be above the bed of the stream. An intermittent stream has limited contribution from the groundwater. During the wet season the water table is above the stream bed and there is a contribution of the base flow to the stream flow. However, during dry seasons the water table drops to a level lower than that of the stream bed and the stream dries up. Excepting for an occasional storm which can produce a short-duration flow, the stream remains dry for the most part of the dry months (Fig. 5.3). An ephemeral stream is one which does not have any base-flow contribution. The annual hydrograph of such a river shows series of short-duration spikes marking flash flows in response to storms (Fig. 5.4). The stream becomes dry soon after the end of

Runoff

143

Fig. 5.3 Intermittent stream the storm flow. Typically an ephemeral stream does not have any well-defined, channel. Most of the rivers in arid zones are of the ephemeral kind. The flow characteristics of a stream depend upon: l The rainfall characteristics, such as magnitude intensity, distribution according to time and space, Fig. 5.4 Ephemeral stream and its variability. l Catchment characteristics such as soil, land use/cover, slope, geology, shape and drainage density. l Climatic factors which influence evapotranspiration. The interrelationship of these factors is extremely complex. However, at the risk of oversimplification, the following points can be noted. l The seasonal variation of rainfall is clearly reflected in the runoff. High stream discharges occur during the monsoon months and low flow which is essentially due to the base flow is maintained during the rest of the year. l The shape of the stream hydrograph and hence the peak flow is essentially controlled by the storm and the physical characteristics of the basin. Evapotranspiration plays a minor role in this. l The annual runoff volume of a stream is mainly controlled by the amount of rainfall and evapotranspiration. The geology of the basin is significant to the extent of deep percolation losses. The land use/cover play an important role in creating infiltration and evapotranspiration opportunities and retarding of runoff.

5.4 RUNOFF VOLUME Yield The total quantity of surface water that can be expected in a given period from a stream at the outlet of its catchment is known as yield of the catchment in that period.

144 Engineering Hydrology Depending upon the period chosen we have annual yield and seasonal yield signifying yield of the catchment in an year and in a specified season respectively. Unless otherwise qualified the term yield is usually used to represent annual yield. The term yield is used mostly by the irrigation engineering professionals in India. The annual yield from a catchment is the end product of various processes such as precipitation, infiltration and evapotranspiration operating on the catchment. Due to the inherent nature of the various parameters involved in the processes, the yield is a random variable. A list of values of annual yield in a number of years constitutes an annual time series which can be analyzed by methods indicated in Chapter 2 (Sec. 2.11) to assign probabilities of occurrences of various events. A common practice is to assign a dependability value (say 75% dependable yield) to the yield. Thus, 75% dependable annual yield is the value that can be expected to be equalled to or exceeded 75% times (i.e. on an average 15 times in a span of 20 years). Similarly, 50% dependable yield is the annual yield value that is likely to be equalled or exceeded 50% of times (i.e. on an average 10 times in 20 years). It should be remembered that the yield of a stream is always related to the natural flow in the river. However, when water is diverted from a stream for use in activities such as irrigation, domestic water supply and industries, the non-consumptive part of the diverted water returns back to the hydrologic system of the basin. Such additional flow, known as return flow, is available for the suitable use and as such is added to the natural flow to estimate the yield. (Details pertaining to the return flow are available in Sec. 5.9). The annual yield of a basin at a site is thus taken as the annual natural water flow in the river at the site plus the return flow to the stream from different uses upstream of the site. The yield of a catchment Y in a period Dt could be expressed by water balance equation (Eq. 5.1) as Y = RN + Vr = Ro + Ab + DS (5.1a) where RN = Natural flow in time Dt Vr = Volume of return flow from irrigation, domestic water supply and industrial use Ro = Observed runoff volume at the terminal gauging station of the basin in time Dt. Ab = Abstraction in time, Dt for irrigation, water supply and industrial use and inclusive of evaporation losses in surface water bodies on the stream. D S = Change in the storage volumes of water storage bodies on the stream. The calculation of natural runoff volume (and hence yield), is of fundamental importance in all surface water resources development studies. The most desirable basis for assessing the yield characteristics of a catchment is to analyze the actual flow records of the stream draining the catchment. However, in general, observed discharge data of sufficient length is unlikely to be available for many catchments. As such, other alternate methods such as the empirical equations and watershed simulations (described in Secs 5.4.3 to 5.4.5) are often adopted. It should be noted that the observed stream flow at a site includes return flow. For small catchments and for catchments where water resources developments are at a small scale, the return flow is likely to be a negligibly small part of the runoff. In the further parts of this chapter the term annual (or seasonal) runoff volume R and the term annual (or seasonal) yield are used synonymously with the implied assumption

Runoff

145

that the return flow is negligibly small. It is emphasized that when return flow is not negligible, it is the natural flow volume that is to be used in hydrological correlations with rainfall.

Rainfall–Runoff Correlation The relationship between rainfall in a period and the corresponding runoff is quite complex and is influenced by a host of factors relating to the catchment and climate. Further, there is the problem of paucity of data which forces one to adopt simple correlations for adequate estimation of runoff. One of the most common methods is to correlate seasonal or annual measured runoff values (R) with corresponding rainfall (P) values. A commonly adopted method is to fit a linear regression line between R and P and to accept the result if the correlation coefficient is nearer unity. The equation of the straight-line regression between runoff R and rainfall P is R = aP + b (5.2) and the values of the coefficient a and b are given by N ( SPR ) - ( SP )( SR ) a= (5.3a) N ( SP 2 ) - ( SP ) 2 and

b=

SR - a ( SP )

(5.3b) N in which N = number of observation sets R and P. The coefficient of correlation r can be calculated as N ( SPR ) - ( SP )( SR ) (5.4) r= [ N ( SP 2 ) - ( SP ) 2 ][ N ( SR 2 ) - ( SR ) 2 ] The value of r lies between 0 and 1 as R can have only positive correlation with P. The value of 0.6 < r < 1.0 indicates good correlation. Further, it should be noted that R ³ 0. For large catchments, sometimes it is found advantageous to have exponential relationship as R = b Pm (5.5) where b and m are constants, instead of the linear relationship given by Eq. (5.2). In that case Eq. (5.5) is reduced to linear form by logarithmic transformation as ln R = m ln P + ln b (5.6) and the coefficients m and ln b are determined by using methods indicated earlier. Since rainfall records of longer periods than that of runoff data are normally available for a catchment, the regression equation [Eq. (5.2) or (5.5)] can be used to generate synthetic runoff data by using rainfall data. While this may be adequate for preliminary studies, for accurate results sophisticated methods are adopted for synthetic generation of runoff data. Many improvements of the above basic rainfall-runoff correlation by considering additional parameters such as soil moisture and antecedent rainfall have been attempted. Antecedent rainfall influences the initial soil moisture and hence the infiltration rate at the start of the storm. For calculation of the annual runoff from the annual rainfall a commonly used antecedent precipitation index Pa is given by (5.7) Pa = aPi + bPi–1 + cPi–2

146 Engineering Hydrology where P i, p i–1 and P i-2 are the annual precipitation in the i th , (i – 1) th and (i – 2)th year and i = current year, a, b and c are the coefficients with their sum equal to unity. The coefficients are found by trial and error to produce best results. There are many other types of antecedent precipitation indices in use to account for antecedent soil moisture condition. For example, in SCS – CN method (Sec. 5.4.5) the sum of past five-day rainfall is taken as the index of antecedent moisture condition. EXAMPLE 5.2 Annual rainfall and runoff values (in cm) of a catchment spanning a period of 21 years are given below. Analyze the data to (a) estimate the 75% and 50% dependable annual yield of the catchment and (b) to develop a linear correlation equation to estimate annual runoff volume for a given annual rainfall value. Year

Annual rainfall (cm)

Annual runoff (cm)

Year

Annual rainfall (cm)

Annual runoff (cm)

1975 1976 1977 1978 1979 1980 1981 1982 1983 1984 1985

118 98 112 97 84 91 138 89 104 80 97

54 45 51 41 21 32 66 25 42 11 32

1986 1987 1988 1989 1990 1991 1992 1993 1994 1995

75 107 75 93 129 153 92 84 121 95

17 32 15 28 48 76 27 18 52 26

SOLUTION: (a) The annual runoff values are arranged in descending order of magnitude and a rank (m) is assigned for each value starting from the highest value (Table 5.1). m The exceedence probability p is calculated for each runoff value as p = . In this N +1 m = rank number and N = number of data sets. (Note that in Table 5.1 three items have the same value of R = 32 cm and for this set p is calculated for the item having the highest value of m, i.e m = 12). For estimating 75% dependable yield, the value of p = 0.75 is read from Table 5.1 by linear interpolation between items having p = 0.773 and p = 0.727. By this method, the 75% dependable yield for the given annual yield time series is found to be R75 = 23.0 cm. Similarly, the 50% dependable yield is obtained by linear interpolation between items having p = 0.545 and p = 0.409 as R50 = 34.0 cm. (b) The correlation equation is written as R = aP + b The coefficients of the best fit straight line for the data are obtained by the least square error method as mentioned in Table 5.1. From the Table 5.1, S P =2132 S R = 759 S PR = 83838 2 2 S P = 224992 S R = 33413 (S R)2 = 576081 N = 21 (S P)2 = 4545424 By using Eq. (5.3-a) N ( SPR ) - ( SP ) ( SR ) (21´ 83838) - (2132 )(759) = = 0.7938 a= 2 2 N ( SP ) - ( SR ) (21 ´ 224992) - (2132) 2

Runoff

147

Table 5.1 Calculations for Example 5.2 1

2

3

P R rainfall runoff Year (cm) (cm) 1975 118 1976 98 1977 112 1978 97 1979 84 1980 91 1981 138 1982 89 1983 104 1984 80 1985 97 1986 75 1987 107 1988 75 1989 93 1990 129 1991 153 1992 92 1993 84 1994 121 1995 95 SUM 2132

54 45 51 41 21 32 66 25 42 11 32 17 32 15 28 48 76 27 18 52 26 759

By Eq. (5.3-b)

4

5

6

P2

R2

PR

13924 9604 12544 9409 7056 8281 19044 7921 10816 6400 9409 5625 11449 5625 8649 16641 23409 8464 7056 14641 9025 224992

2916 2025 2601 1681 441 1024 4356 625 1764 121 1024 289 1024 225 784 2304 5776 729 324 2704 676 33413

6372 4410 5712 3977 1764 2912 9108 2225 4368 880 3104 1275 3424 1125 2604 6192 11628 2484 1512 6292 2470 83838

7

8 9 R (Sorted annual Exceedence rank, runoff) probability, m (cm) p 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21

76 66 54 52 51 48 45 42 41 32 32 32 28 27 26 25 21 18 17 15 11

0.045 0.091 0.136 0.182 0.227 0.273 0.318 0.364 0.409 0.545 0.591 0.636 0.682 0.727 0.773 0.818 0.864 0.909 0.955

(759) - 0.7938 ´ (2138) = = –44.44 N 21 Hence the required annual rainfall–runoff relationship of the catchment is given by R = 0.7938 P – 44.44 with both P and R being in cm and R ³ 0. By Eq. (5.4) coefficient of correlation N ( SPR ) - ( SP )( SR ) r= 2 [ N ( SP ) - ( SP ) 2 ][ N ( SR 2 ) - ( SR ) 2 ] (21 ´ 83838 - (2132) (759) = = 0.949 [(21 ´ 224992) - (4545424)][(21 ´ 33413) - (576081) As the value of r is nearer to unity the correlation is very good. Figure 5.5 represents the data points and the best fit straight line.

b=

SR - a ( SP )

Empirical Equations The importance of estimating the water availability from the available hydrologic data for purposes of planning water-resource projects was recognised by engineers even in

148 Engineering Hydrology

Fig. 5.5 Annual Rainfall–Runoff Correlation—Example 5.2 the last century. With a keen sense of observation in the region of their activity many engineers of the past have developed empirical runoff estimation formulae. However, these formulae are applicable only to the region in which they were derived. These formulae are essentially rainfall–runoff relations with additional third or fourth parameters to account for climatic or catchment characteristics. Some of the important formulae used in various parts of India are given below. Binnie’s Percentages Sir Alexander Binnie measured the runoff from a small catchment near Nagpur (Area of 16 km2) during 1869 and 1872 and developed curves of cumulative runoff against cumulative rainfall. The two curves were found to be similar. From these he established the percentages of runoff from rainfall. These percentages have been used in Madhya Pradesh and Vidarbha region of Maharashtra for the estimation of yield. Barlow’s Tables Barlow, the first Chief Engineer of the Hydro-Electric Survey of India (1915) on the basis of his study in small catchments (area ~130 km2) in Uttar Pradesh expressed runoff R as R = Kb P (5.8) where Kb = runoff coefficient which depends upon the type of catchment and nature of monsoon rainfall. Values of Kb are given in Table 5.2. Table 5.2 Barlow’s Runoff Coefficient Kb in Percentage (Developed for use in UP) Class A B C D E

Description of catchment Flat, cultivated and absorbent soils Flat, partly cultivated, stiff soils Average catchment Hills and plains with little cultivation Very hilly, steep and hardly any cultivation

Values of Kb (percentage) Season 1 Season 2 Season 3 7 12 16 28 36

Season 1: Light rain, no heavy downpour Season 2: Average or varying rainfall, no continuous downpour Season 3: Continuous downpour

10 15 20 35 45

15 18 32 60 81

Runoff

149

Strange’s Tables Strange (1892) studied the available rainfall and runoff in the border areas of present-day Maharashtra and Karnataka and has obtained yield ratios as functions of indicators representing catchment characteristics. Catchments are classified as good, average and bad according to the relative magnitudes of yield they give. For example, catchments with good forest/vegetal cover and having soils of high permeability would be classified as bad, while catchments having soils of low permeability and having little or no vegetal cover is termed good. Two methods using tables for estimating the runoff volume in a season are given. 1. Runoff Volume from Total Monsoon Season Rainfall A table giving the runoff volumes for the monsoon period (i.e. yield during monsoon season) for different total monsoon rainfall values and for the three classes of catchments (viz. good, average and bad) are given in Table 5.3-a. The correlation equations of best fitting lines relating percentage yield ratio (Yr) to precipitation (P) could be expressed as Table 5.3(a) Strange’s Table of Total Mansoon Rainfall and estimated Runoff Total Monsoon rainfall (inches)

Total Monsoon rainfall (mm)

1.0 2.0 3.0 4.0 5.0 6.0 7.0 8.0 9.0 10.0 11.0 12.0 13.0 14.0 15.0 16.0 17.0 18.0 19.0 20.0 21.0 22.0 23.0 24.0

25.4 50.8 76.2 101.6 127.0 152.4 177.8 203.2 228.6 254.0 279.4 304.8 330.2 355.6 381.0 406.4 431.8 457.2 482.6 508.0 533.4 558.8 584.2 609.6

Percentage of Runoff to rainfall Good Average Bad catch- catch- catchment ment ment 0.1 0.2 0.4 0.7 1.0 1.5 2.1 2.8 3.5 4.3 5.2 6.2 7.2 8.3 9.4 10.5 11.6 12.8 13.9 15.0 16.1 17.3 18.4 19.5

0.1 0.2 0.3 0.5 0.7 1.1 1.5 2.1 2.6 3.2 3.9 4.6 5.4 6.2 7.0 7.8 8.7 9.6 10.4 11.3 12.0 12.9 13.8 14.6

0.1 0.1 0.2 0.3 0.5 0.7 1.0 1.4 1.7 2.1 2.6 3.1 3.6 4.1 4.7 5.2 5.8 6.4 6.9 7.5 8.0 8.6 9.2 9.7

Total Monsoon rainfall (inches)

Total Monsoon rainfall (mm)

31.0 32.0 33.0 34.0 35.0 36.0 37.0 38.0 39.0 40.0 41.0 42.0 43.0 44.0 45.0 46.0 47.0 48.0 49.0 50.0 51.0 52.0 53.0 54.0

787.4 812.8 838.2 863.6 889.0 914.4 939.8 965.2 990.6 1016.0 1 041.4 1066.8 1092.2 1117.6 1143.0 1168.4 1193.8 1219.2 1244.6 1270.0 1295.4 1320.8 1346.2 1371.6

Percentage of Runoff to rainfall Good Average Bad catch- catch- catchment ment ment 27.4 28.5 29.6 30.8 31.9 33.0 34.1 35.3 36.4 37.5 38.6 39.8 40.9 42.0 43.1 44.3 45.4 46.5 47.6 48.8 49.9 51.0 52.1 53.3

20.5 21.3 22.2 23.1 23.9 24.7 25.5 26.4 27.3 28.1 28.9 29.8 30.6 31.5 32.3 33.2 34.0 34.8 35.7 36.6 37.4 38.2 39.0 39.9

13.7 14.2 14.8 15.4 15.9 16.5 17.0 17.6 18.2 18.7 19.3 19.9 20.4 21.0 21.5 22.1 22.7 23.2 23.8 24.4 24.9 25.5 26.0 26.6 (Contd.)

150 Engineering Hydrology (Contd.) 25.0 26.0 27.0 28.0 29.0 30.0

635.0 660.4 685.8 711.2 736.6 762.0

20.6 21.8 22.9 24.0 25.1 26.3

For Good catchment: For P < 250 mm, For 250 < P < 760 For 760 < P < 1500 For Average catchment: For P < 250 mm, For 250 < P < 760 For 760 < P < 1500 For Bad catchment: For P < 250 mm,

15.4 16.3 17.1 18.0 18.8 19.7

10.3 10.9 11.4 12.0 12.5 13.1

55.0 56.0 57.0 58.0 59.0 60.0

1397.0 1422.4 1447.8 1473.2 1498.6 1524.0

54.4 55.5 56.6 57.8 58.9 60.0

40.8 41.6 42.4 43.3 44.4 45.0

Yr = 7 ´ 10–5 P2 – 0.0003 P having r 2 = 0.9994 Yr = 0.0438 P – 7.1671 having r 2 = 0.9997 Yr = 0.0443 P – 7.479 having r2 = 1.0 Yr = 6 ´ 10–5 P2 – 0.0022 P + 0.1183 having r2 = 0.9989 Yr = 0.0328 P – 5.3933 having r 2 = 0.9997 Yr = 0.0333 P – 5.7101 having r2 = 0.9999

27.2 27.7 28.3 28.9 29.41 30.0

(5.9a) (5.9b) (5.9c) (5.10a) (5.10b) (5.10c)

Yr = 4 ´ 10–5 P2 – 0.0011 P + 0.0567 having r2 = 0.9985 (5.11a) For 250 < P < 760 Yr = 0.0219 P – 3.5918 having r 2 = 0.9997 (5.11b) For 760 < P < 1500 Yr = 0.0221 P – 3.771 having r 2 = 1.0 (5.11c) where Yr = Percentage yield ratio = ratio of seasonal runoff to seasonal rainfall in percentage and P = monsoon season rainfall in mm. Since there is no appreciable runoff due to the rains in the dry (non-monsoon) period, the monsoon season runoff volume is recommended to be taken as annual yield of the catchment. This table could be used to estimate the monthly yields also in the monsoon season. However, it is to be used with the understanding that the table indicates relationship between cumulative monthly rainfall starting at the beginning of the season and cumulative runoff, i.e. a double mass curve relationship. Example 5.3 illustrates this procedure. 2. Estimating the Runoff Volume from Daily Rainfall In this method Strange in a most intuitive way recognizes the role of antecedent moisture in modifying the runoff volume due to a rainfall event in a given catchment. Daily rainfall events are considered and three states of antecedent moisture conditions prior to the rainfall event as dry, damp and wet are recognized. The classification of these three states is as follows: Wetting Process (a) Transition from Dry to Damp (i) 6 mm rainfall in the last 1 day (iii) 25 mm in the last 7 days (ii) 12 mm in the last 3 days (iv) 38 mm in the last 10 days (b) Transition from Damp to Wet (i) 8 mm rainfall in the last 1 day (iii) 25 mm in the last 3 days (ii) 12 mm in the last 2 days (iv) 38 mm in the last 5 days (c) Direct Transition from Dry to Wet Whenever 64 mm rain falls on the previous day or on the same day.

Runoff

151

Drying Process (d) Transition from Wet to Damp (i) 4 mm rainfall in the last 1 day (iii) 12 mm in the last 4 days (ii) 6 mm in the last 2 days (iv) 20 mm in the last 5 days (e) Transition from Damp to Dry (i) 3 mm rainfall in the last 1 day (iii) 12 mm in the last 7 days (ii) 6 mm in the last 3 days (iv) 15 mm in the last 10 days The percentage daily rainfall that will result in runoff for average (yield producing) catchment is given in Table 5.3(b). For good (yield producing) and bad (yield producing) catchments add or deduct 25% of the yield corresponding to the average catchment. Table 5.3(b) Daily rainfall (mm) 6 13 19 25 32 38 45 51 64 76 102

Strange’s Table of Runoff Volume from Daily Rainfall for an Average Catchment Percentage of runoff volume to daily rainfall when original state of the ground was Dry Damp Wet — — — 3 5 6 8 10 15 20 30

— 6 8 11 14 16 19 22 29 37 50

8 12 16 18 22 25 30 34 43 55 70

Best fitting linear equations for the above table would read as below with Ks = runoff volume percentage and P = daily rainfall (mm): For Dry AMC: Ks = 0.5065 P – 2.3716 for P > 20 mm (5.12a) with coefficient of determination r2 = 0.9947 For Damp AMC: Ks = 0.3259 P – 5.1079 for P > 7 mm (5.12b) with coefficient of determination r2 = 0. 9261 (5.12c) For Wet AMC: Ks = 0.6601 P + 2.0643 with coefficient of determination r2 = 0.9926 Use of Strange’s Tables Strange’s monsoon rainfall-runoff table (Table 5.3-a) and Table (5.3-b) for estimating daily runoff corresponding to a daily rainfall event are in use in parts of Karnataka, Andhra Pradesh and Tamil Nadu. A calculation procedure using Table (5.3-a) to calculate monthly runoff volumes in a monsoon season using cumulative monthly rainfalls is shown in Example 5.3. EXAMPLE 5.3 Monthly rainfall values of the 50% dependable year at a site selected for construction of an irrigation tank is given below. Estimate the monthly and annual runoff volume of this catchment of area 1500 ha. [Assume the catchment classification as Good catchment].

152 Engineering Hydrology Month Monthly rainfall (mm)

June

July

Aug

Sept

Oct

90

160

145

22

240

SOLUTION: Calculations are shown in the Table 5.4 given below. Table 5.4 Calculation of Monthly Yields by Strange’s Method—Example 5.3 No.

Month

1. Monthly Rainfall (mm) 2. Cumulative monthly rainfall (mm) 3. Runoff/rainfall as % (From Strange’s Table 5.3-a) 4. Cumulative Runoff (mm) 5. Monthly Runoff (mm)

June

July

August September October

90 90

160 250

145 395

22 417

240 657

0.56

4.17

10.01

11.08

21.69

0.50 0.50

10.43 9.92

39.54 29.11

46.20 6.66

142.50 96.30

Row 4 is obtained by using Strange’s Tables 5.3. Note that cumulative monthly rainfall is used to get the cumulative runoff-ratio percentage at any month. Total monsoon runoff = 142.50 mm = (142.5/1000) ´ (1500 ´ 104)/106 Mm3 = 2.1375 Mm3 Annual Runoff is taken as equal to monsoon runoff.

Inglis and DeSouza Formula As a result of careful stream gauging in 53 sites in Western India, Inglis and DeSouza (1929) evolved two regional formulae between annual runoff R in cm and annual rainfall P in cm as follows: 1. For Ghat regions of western India R = 0.85 P – 30.5 (5.13) 2. For Deccan plateau 1 R= P (P – 17.8) (5.14) 254 Khosla’s Formula Khosla (1960) analysed the rainfall, runoff and temperature data for various catchments in India and USA to arrive at an empirical relationship between runoff and rainfall. The time period is taken as a month. His relationship for monthly runoff is Rm = Pm – Lm (5.15) and Lm = 0.48 Tm for Tm > 4.5° C where Rm = monthly runoff in cm and Rm ³ 0 Pm = monthly rainfall in cm Lm = monthly losses in cm Tm = mean monthly temperature of the catchment in ° C For Tm £ 4.5°C, the loss Lm may provisionally be assumed as T°C Lm (cm)

Annual runoff = SRm

4.5 2.17

–1 1.78

–6.5 1.52

Runoff

153

Khosla’s formula is indirectly based on the water-balance concept and the mean monthly catchment temperature is used to reflect the losses due to evapotranspiration. The formula has been tested on a number of catchments in India and is found to give fairly good results for the annual yield for use in preliminary studies. EXAMPLE 5.4 For a catchment in UP, India, the mean monthly temperatures are given. Estimate the annual runoff and annual runoff coefficient by Khosla’s method. Month Temp°C Rainfall (Pm)(cm)

Jan

Feb Mar Apr May Jun

Jul Aug Sep Oct Nov Dec

12

16

21

27

31

34

31

29

28

29

19

14

4

4

2

2

12

32

29

16

2

1

2

SOLUTION: In Khosla’s formula applicable to the present case, Rm = Pm – Lm with Lm =

(0.48 ´ T °C) having a maximum value equal to corresponding Pm. The calculations are shown below: Month

Jan Feb Mar Apr May Jun

Rainfall (Pm)(cm) 4 Temp°C 12 Lm (cm) 4 Runoff (Rm)(cm) 0

4 16 4

2 21 2

0 27 0

2 31 2

12 34 12

Jul Aug Sep Oct Nov Dec 32 29 16 31 29 28 14.9 13.9 13.4 17.1 15.1

2.6

2 29 2

1 19 1

2 14 2

Total annual runoff = 34.8 cm Annual runoff coefficient = (Annual runoff/Annual rainfall) = (34.8/116.0) = 0.30

Watershed Simulation The hydrologic water-budget equation for the determination of runoff for a given period is written as (5.16) R = Rs + G0 = P – Eet – DS in which Rs = surface runoff, P = precipitation, Eet = actual evapotranspiration, G0 = net groundwater outflow and DS = change in the soil moisture storage. The sum of Rs and G0 is considered to be given by the total runoff R, i.e. streamflow. Starting from an initial set of values, one can use Eq. (5.16) to calculate R by knowing values of P and functional dependence of Eet, DS and infiltration rates with catchment and climatic conditions. For accurate results the functional dependence of various parameters governing the runoff in the catchment and values of P at short time intervals are needed. Calculations can then be done sequentially to obtain the runoff at any time. However, the calculation effort involved is enormous if attempted manually. With the availability of digital computers the use of water budgeting as above to determine the runoff has become feasible. This technique of predicting the runoff, which is the catchment response to a given rainfall input is called deterministic watershed simulation. In this the mathematical relationships describing the interdependence of various parameters in the system are first prepared and this is called the model. The model is then calibrated, i.e. the numerical values of various coefficients determined by simulating the known rainfall-runoff records. The accuracy of the model is further checked by reproducing the results of another string of rainfall data for which runoff values are

154 Engineering Hydrology known. This phase is known as validation or verification of the model. After this, the model is ready for use. Crawford and Linsley (1959) pioneered this technique by proposing a watershed simulation model known as the Stanford Watershed Model (SWM). This underwent successive refinements and the Stanford Watershed Model-IV (SWM-IV) suitable for use on a wide variety of conditions was proposed in 1966. The flow chart of SWM-IV is shown in Fig. 5.6. The main inputs are hourly precipitation and daily evapotranspiration in addition to physical description of the catchment. The model considers the soil in three zones with distinct properties to simulate evapotranspiration, infiltration, overland flow, channel flow, interflow and baseflow phases of the runoff phenomenon. For calibration about 5 years of data are needed. In the calibration phase, the initial guess value of parameters are adjusted on a trial-and-error basis until the simulated response matches the recorded values. Using an additional length of rainfall-runoff of about 5 years duration, the model is verified for its ability to give proper response. A detailed description of the application of SWM to an Indian catchment is given in Ref. 11.

Fig. 5.6 Flow chart of SWM-IV Based on the logic of SWM-IV many models and improved versions such as HSP (1966), SSARR (1968) and KWM (1970) were developed during late sixties and seventies. These models which simulate stream flow for long periods of time are called

Runoff

155

Continuous Simulated Models. They permit generation of simulated long records for yield, drought and flood flow studies. In the early 1980s there were at least 75 hydrologic simulation models that were available and deemed suitable for small watersheds. In the past two decades considerable effort has been directed towards the development of process-based, spatially explicit, and physically-based models such as MIKE SHE (Refsgaard and Storm, 1955), and GSSHA—Gridded Surface/Subsurface Hydrologic Analysis (Downer et al., 2006). These are new generation of models that utilize GIS technology.

SCS-CN Method of Estimating Runoff Volume SCS-CN method, developed by Soil Conservation Services (SCS) of USA in 1969, is a simple, predictable, and stable conceptual method for estimation of direct runoff depth based on storm rainfall depth. It relies on only one parameter, CN. Currently, it is a wellestablished method, having been widely accepted for use in USA and many other countries. The details of the method are described in this section. Basic Theory The SCS-CN method is based on the water balance equation of the rainfall in a known interval of time Dt, which can be expressed as P = Ia + F + Q (5.17) where P = total precipitation, Ia = initial abstraction, F = Cumulative infiltration excluding Ia and Q = direct surface runoff (all in units of volume occurring in time Dt). Two other concepts as below are also used with Eq. (5.17). (i) The first concept is that the ratio of actual amount of direct runoff (Q) to maximum potential runoff (= P– Ia) is equal to the ratio of actual infiltration (F) to the potential maximum retention (or infiltration), S. This proportionality concept can be schematically shown as in Fig. 5.7 Q Fig. 5.7 Proportionality F Thus = (5.18) concept P - Ia S (ii) The second concept is that the amount of initial abstraction (Ia) is some fraction of the potential maximum retention (S). (5.19) Thus Ia = lS Combining Eqs. (5.18) and (5.19), and using (5.17) Q=

( P - I a )2

=

( P - l S )2 for P > l S P + (1 - l ) S

(5.20a) P - Ia + S Further Q = 0 for P £ l S (5.20b) For operation purposes a time interval D t = 1 day is adopted. Thus P = daily rainfall and Q = daily runoff from the catchment. Curve Number (CN) The parameter S representing the potential maximum retention depends upon the soil–vegetation–land use complex of the catchment and also upon the antecedent soil moisture condition in the catchment just prior to the commencement of the rainfall event. For convenience in practical application the Soil Conservation Services (SCS) of USA has expressed S (in mm) in terms of a dimensionless parameter CN (the Curve number) as

156 Engineering Hydrology

25400 100 ö - 254 = 254 æ -1 (5.21) è CN ø CN The constant 254 is used to express S in mm. The curve number CN is now related to S as 25400 CN = (5.22) S + 254 and has a range of 100 ³ CN ³ 0. A CN value of 100 represents a condition of zero potential retention (i.e. impervious catchment) and CN = 0 represents an infinitely abstracting catchment with S = ¥. This curve number CN depends upon l Soil type l Land use/cover l Antecedent moisture condition S=

Soils In the determination of CN, the hydrological soil classification is adopted. Here, soils are classified into four classes A, B, C and D based upon the infiltration and other characteristics. The important soil characteristics that influence hydrological classification of soils are effective depth of soil, average clay content, infiltration characteristics and permeability. Following is a brief description of four hydrologic soil groups: l Group-A: (Low Runoff Potential): Soils having high infiltration rates even when thoroughly wetted and consisting chiefly of deep, well to excessively drained sands or gravels. These soils have high rate of water transmission. [Example: Deep sand, Deep loess and Aggregated silt] l Group-B: (Moderately Low runoff Potential): Soils having moderate infiltration rates when thoroughly wetted and consisting chiefly of moderately deep to deep, moderately well to well-drained soils with moderately fine to moderately coarse textures. These soils have moderate rate of water transmission. [Example: Shallow loess, Sandy loam, Red loamy soil, Red sandy loam and Red sandy soil] l Group-C: (Moderately High Runoff Potential): Soils having low infiltration rates when thoroughly wetted and consisting chiefly of moderately deep to deep, moderately well to well drained soils with moderately fine to moderately coarse textures. These soils have moderate rate of water transmission. [Example: Clayey loam, Shallow sandy loam, Soils usually high in clay, Mixed red and black soils] l Group-D: (High Runoff Potential): Soils having very low infiltration rates when thoroughly wetted and consisting chiefly of clay soils with a high swelling potential, soils with a permanent high-water table, soils with a clay pan, or clay layer at or near the surface, and shallow soils over nearly impervious material. [Example: Heavy plastic clays, certain saline soils and deep black soils]. Antecedent Moisture Condition (AMC) Antecedent Moisture Condition (AMC) refers to the moisture content present in the soil at the beginning of the rainfall-runoff event under consideration. It is well known that initial abstraction and infiltration are governed by AMC. For purposes of practical application three levels of AMC are recognized by SCS as follows: AMC-I: Soils are dry but not to wilting point. Satisfactory cultivation has taken place. AMC-II: Average conditions AMC-III: Sufficient rainfall has occurred within the immediate past 5 days. Saturated soil conditions prevail.

Runoff

157

The limits of these three AMC classes, based on total rainfall magnitude in the previous 5 days, are given in Table 5.5. It is to be noted that the limits also depend upon the seasons: two seasons, viz. growing season and dormant season are considered. Table 5.5 Antecedent Moisture Conditions (AMC) for Determining the Value of CN AMC Type

Total Rain in Previous 5 days Dormant Season Growing Season

I II III

Less than 13 mm 13 to 28 mm More than 28 mm

Less than 36 mm 36 to 53 mm More than 53 mm

Land Use The variation of CN under AMC-II, called CNII, for various land use conditions commonly found in practice are shown in Table 5.6(a, b and c). Table 5.6(a) Runoff Curve Numbers [CNII] for Hydrologic Soil Cover Complexes [Under AMC-II Conditions] Land Use

Cover Treatment or Hydrologic practice condition

Cultivated Cultivated

Straight row Contoured

Cultivated

Contoured & Terraced Bunded

Cultivated Cultivated Orchards Forest Pasture Wasteland Roads (dirt) Hard surface areas

Poor Good Poor Good Poor Good

Paddy With understory cover Without understory cover Dense Open Scrub Poor Fair Good

A

Hydrologic soil group B C D

76 70 65 66 62 67 59 95 39 41 26 28 33 68 49 39 71 73

86 79 75 74 71 75 69 95 53 55 40 44 47 79 69 61 80 83

90 84 82 80 77 81 76 95 67 69 58 60 64 86 79 74 85 88

93 88 86 82 81 83 79 95 71 73 61 64 67 89 84 80 88 90

77

86

91

93

[Source: Ref.7]

Note: Sugarcane has a separate supplementary Table of CNII values (Table 5.6(b)). The conversion of CNII to other two AMC conditions can be made through the use of following correlation equations.10 CN II For AMC-I: CNI = (5.23) 2.281 - 0.01281 CN II

158 Engineering Hydrology Table 5.6(b) CNII Values for Sugarcane Cover and treatment A Limited cover, Straight Row Partial cover, Straight row Complete cover, Straight row Limited cover, Contoured Partial cover, Contoured Complete cover, Contoured

[Source: Ref.7]

Hydrologic soil group B C

67 49 39 65 25 6

78 69 61 75 59 35

85 79 74 82 45 70

D 89 84 80 86 83 79

Table 5.6(c) CN II Values for Suburban and Urban Land Uses (Ref. 3) Cover and treatment A Open spaces, lawns, parks etc (i) In good condition, grass cover in more than 75% area (ii) In fair condition, grass cover on 50 to 75% area Commercial and business areas (85% impervious) Industrial Districts (72% impervious) Residential, average 65% impervious Paved parking lots, paved roads with curbs, roofs, driveways, etc Streets and roads Gravel Dirt

Hydrologic soil group B C D

39

61

74

80

49 89 81 77 98

69 92 88 85 98

79 94 91 90 98

84 95 93 92 98

76 72

85 82

89 87

91 89

CN II (5.24) 0.427 + 0.00573 CN II The equations (5.23) and (5.24) are applicable in the CNII, range of 55 to 95 which covers most of the practical range. Values of CNI, and CNIII covering the full range of CNII are available in Refs 3 and 7. Procedures for evaluation of CN from data on small watersheds are available in Ref. 7.

For AMC-III:

CNIII =

Value of l On the basis of extensive measurements in small size catchments SCS (1985) adopted l = 0.2 as a standard value. With this Eq. (5.20-a) becomes

( P - 0.2 S )2 for P > 0.2S (5.25) P + 0.8 S where Q = daily runoff, P = daily rainfall and S = retention parameter, all in units of mm. Equation 5.25, which is well established, is called as the Standard SCS-CN equation. Q=

SCS-CN Equation for Indian Conditions Values of l varying in the range 0.1 £ l £ 0.4 have been documented in a number of studies from various geographical locations, which include USA and many other countries. For use in Indian conditions l = 0.1 and 0.3 subject to certain constraints of soil type and AMC type has been recommended (Ref. 7) as below:

Runoff

159

( P - 0.1 S )2 for P > 0.l S, P + 0.9 S valid for Black soils under AMC of Type II and III (5.26) 2 ( P - 0.3 S ) Q= for P > 0.3S valid for Black soils under P + 0.7 S AMC of Type 1 and for all other soils having AMC of types I, II and III (5.27) These Eqs. (5.26 & 5.27) along with Table 5.6 (a & b) are recommended (Ref. 7) for use in Indian conditions in place of the Standard SCN-CN equation. Q=

Procedure for Estimating Runoff Volume from a Catchment (i) Land use/cover information of the catchment under study is derived based on interpretation of multi-season satellite images. It is highly advantageous if the GIS database of the catchment is prepared and land use/cover data is linked to it. (ii) The soil information of the catchment is obtained by using soil maps prepared by National Bureau of Soil Survey and Land use planning (NBSS & LUP) (1966). Soil data relevant to the catchment is identified and appropriate hydrological soil classification is made and the spatial form of this data is stored in GIS database. (iii) Available rainfall data of various rain gauge stations in and around the catchment is collected, screened for consistency and accuracy and linked to the GIS database. For reasonable estimate of catchment yield it is desirable to have a rainfall record of at least 25 years duration. (iv) Thiessen polygons are established for each identified rain gauge station. (v) For each Thiessen cell, appropriate area weighted CNII value is established by adequate consideration of spatial variation of land use and/cover and soil types. Further, for each cell, corresponding CNI and CNIII values are determined by using Eqs. (5.23) and (5.24). (vi) Using the relevant SCS-CN equations sequentially with the rainfall data, the corresponding daily runoff series is derived for each cell. From this the needed weekly/monthly/annual runoff time series is derived. Further, by combining the results of various cells constituting the catchment, the corres-ponding catchment runoff time series is obtained. (vii) Appropriate summing of the above time series, yields seasonal/annual runoff volume series and from this the desired dependable catchment yield can be estimated. Current Status of SCS-CN Method The SCS-CN method has received considerable applications and research study since its introduction in 1969. Recently, Ponce and Hawkins10 (1996) have critically examined the method, clarified its capabilities, limitations and uses. There is a growing body of literature on this method and a good bibliography on this subject is available in Ref. 10. The chief advantages of SCS-CN method can be summed up as: l It is a simple, predictable, and stable conceptual method for estimation of direct runoff depth based on storm rainfall depth, supported by empirical data. l It relies on only one parameter, CN. Even though CN can have a theoretical range of 0–100, in practice it is more likely to be in the range 40–98.

160 Engineering Hydrology l l

It features readily grasped and reasonably well-documented environmental inputs. It is a well-established method, having been widely accepted for use in USA and many other countries. The modifications suggested by the Ministry of Agriculture, Govt. of India 7, (1972), make its use effective for Indian conditions.

EXAMPLE 5.5 In a 350 ha watershed the CN value was assessed as 70 for AMC-III. (a) Estimate the value of direct runoff volume for the following 4 days of rainfall. The AMC on July 1st was of category III. Use standard SCS-CN equations. Date Rainfall (mm)

July 1

July 2

July 3

July 4

50

20

30

18

(b) What would be the runoff volume if the CNIII value were 80?

SOLUTION:

(a) Given CNIII = 70 Q= =

S = (25400/70) – 254 = 108.6

( P - 0.2 S ) 2 P + 0.8 S

for P > 0.2S

[ P - (0.2 ´ 108.86 )2 P + (0.8 ´ 108.86)

=

[ P - 21.78]2

Date

P (mm)

July 1 July 2 July 3 July 4 Total

50 20 30 18 118

P + 87.09

for P > 21.78 mm

Q (mm) 5.81 0 0.58 0 6.39

Total runoff volume over the catchment Vr = 350 ´ 104 ´ 6.39/(l000) = 22,365 m3 (b) Given CNIII = 80 S = (25400/80) – 254 = 63.5 Q= =

( P - 0.2 S ) 2 P + 0.8 S

for P > 0.2 S

[ P - (0.2 ´ 63.5)]2 P + (0.8 ´ 63.5)

=

[ P - 12.7]2 P + 50.8

for P > 12.7 mm

Date

P (mm)

Q (mm)

July 1 July 2 July 3 July 4 Total

50 20 30 18 118

13.80 0.75 3.70 0.41 18.66

Total runoff volume over the catchment Vr = 350 ´ 104 ´ 18.66/(1000) = 65,310 m3

Runoff

161

EXAMPLE 5.6 A small watershed is 250 ha in size has group C soil. The land cover can be classified as 30% open forest and 70% poor quality pasture. Assuming AMC at average condition and the soil to be black soil, estimate the direct runoff volume due to a rainfall of 75 mm in one day. SOLUTION: AMC = II. Hence CN = CN(II). Soil = Black soil. Referring to Table (5.6-a) for C-group soil

Land use Open forest Pasture (poor) Total

%

CN

Product

30 70 100

60 86

1800 6020 7820

Average CN = 7820/100 = 78.2 S = (25400/78.2) – 254 = 70.81 The relevant runoff equation for Black soil and AMC-II is Q=

( P - 0.1 S ) 2

[75 - (0.1 ´ 70.81)]2

= 33.25 mm P + 0.9 S 75 + (0.9 ´ 70.81) Total runoff volume over the catchment Vr = 250 ´ 104 ´ 33.25/(1000) = 83,125 m3 =

EXAMPLE 5.7 The land use and soil characteristics of a 5000 ha watershed are as follows: Soil: Not a black soil. Hydrologic soil classification: 60% is Group B and 40% is Group C Land Use: Hard surface areas = 10% Waste Land = 5% Orchard (without understory cover) = 30% Cultivated (Terraced), poor condition = 55% Antecedent rain: The total rainfall in past five days was 30 mm. The season is dormant season. (a) Compute the runoff volume from a 125 mm rainfall in a day on the watershed (b) What would have been the runoff if the rainfall in the previous 5 days was 10 mm? (c) If the entire area is urbanized with 60% residential area (65% average impervious area), 10% of paved streets and 30% commercial and business area (85% impervious), estimate the runoff volume under AMC-II condition for one day rainfall of 125 mm. SOLUTION:

(a) Calculation of weighted CN From Table 5.5 AMC = Type III. Using Table (5.6-a) weighted CNII is calculated as below: Land use Hard surface Waste land Orchard Cultivated land Total

Total (%) 10 5 30 55

Soil Group B (60%) % CN Product 6 3 18 33

86 80 55 71

516 240 990 2343 4089

Soil Group C (40%) % CN Product 4 2 12 22

91 85 69 77

364 170 828 1694 3056

162 Engineering Hydrology Weighted CN =

(4089+ 3056)

= 71.45

100

71.45 = 85.42 0.427 + (0.00573 ´ 71.45) Since the soil is not a black soil, Eq. (5.27) is used to compute the surface runoff.

By Eq. (5.24) CNIII =

Q= S= Q=

( P - 0.3 S ) 2 P + 0.7 S

for P > 0.3S and

25400 – 254 = (25400/85.42) – 254 = 43.35 CN

[125 - (0.3 ´ 43.35)]2

= 80.74 mm 125 + (0.7 ´ 43.35) Total runoff volume over the catchment Vr = 5000 ´ 104 ´ 80.74/(1000) = 4,037,000 m3 = 4.037 Mm3 (b) Here AMC = Type I 71.45 Hence CNI = = 52.32 2.281 - (0.01281 ´ 71.45) S = (25400/52.32) – 254 = 231.47

[125 - (0.3 ´ 231.47)]2

= 10.75 mm 125 + (0.7 ´ 231.47) Total runoff volume over the catchment Vr = 5000 ´ 104 ´ 10.75/(1000) = 537500 m3 = 0.5375 Mm3 (c) From Table 5.5 AMC = Type III. Using Table 5.6-c weighted CNII is calculated as below: Q=

Land use (%)

Total %

Residential area (65% imp) Commercial area (85% imp) Paved roads Total

Soil Group B (60%) % CN Product

Soil Group C (40%) % CN Product

60

36

85

3060

24

90

2160

30

18

92

1656

12

94

1128

10

6

98

588 5304

4

98

392 3680

Weightd CNII = By Eq. (5.24)

CNIII =

(5304 + 3680) 100

= 89.8

89.8 = 95.37 0.427 + (0.00573 ´ 89.8)

25400 – 254 = (25400/95.37) – 254 = 12.33 CN Since the soil is not a black soil, Eq. (5.27) is used to compute the surface runoff volume.

S=

Q=

( P - 0.3 S )2 P + 0.7 S

for P > 0.3S and

Runoff

Q=

163

[125- (0.3 ´ 12.33)]2

= 110.11 mm 125 + (0.7 ´ 12.33) Total runoff volume over the catchment Vr = 5000 ´ 104 ´ 110.11/(1000) = 5,505,500 m3 = 5.5055 Mm3

CN and C of Rational Formula SCS-CN method estimates runoff volume while the rational formula (Chapter 7, Sec. 7.2) estimates runoff rate based on the runoff coefficient C. CN and C of are not easily related even though they depend on the same set of parameters. For an infinite sponge C is 0 and CN is 0. Similarly for an impervious surface C is 1.0 and CN is 100. While the end points in the mapping are easily identifiable the relationship between CN and C are nonlinear. In a general sense, high Cs are likely to be found where CN values are also high.

5.5 Flow–Duration Curve It is well known that the streamflow varies over a water year. One of the popular methods of studying this streamflow variability is through flow-duration curves. A flow-duration curve of a stream is a plot of discharge against the per cent of time the flow was equalled or exceeded. This curve is also known as discharge-frequency curve. The streamflow data is arranged in a descending order of discharges, using class intervals if the number of individual values is very large. The data used can be daily, weekly, ten daily or monthly values. If N number of data points are used in this listing, the plotting position of any discharge (or class value) Q is Pp =

m ´ 100% N +1

(5.28)

where m is the order number of the discharge (or class value), Pp = percentage probability of the flow magnitude being equalled or exceeded. The plot of the discharge Q against Pp is the flow duration curve (Fig. 5.8). Arithmetic scale paper, or semi-log or log-log paper is used depending upon the range of data and use of the plot. The flow duration curve repreFig. 5.8 Flow Duration Curve sents the cumulative frequency distribution and can be considered to represent the streamflow variation of an average year. The ordinate Qp at any percentage probability Pp represents the flow magnitude in an average year that can be expected to be equalled or exceeded Pp per cent of time and is termed as Pp % dependable flow. In a perennial river Q100 = 100% dependable flow is a finite value. On the other hand in an intermittent or ephemeral river the streamflow is zero for a finite part of the year and as such Q100 is equal to zero.

164 Engineering Hydrology The following characteristics of the flow duration curve are of interest. l The slope of a flow duration curve depends upon the interval of data selected. For example, a daily stream flow data gives a steeper curve than a curve based on monthly data for the same stream. This is due to the smoothening of small peaks in the monthly data. l The presence of a reservoir in a stream considerably modifies the virgin-flow duration curve depending on the nature of flow regulation. Figure 5.9 shows the typical reservoir regulation effect. l The virgin-flow duration curve when plotted on a log probability paper plots as a straight line at least over the central region. From this property, various coefficients expressing the variability of the flow in a stream can be developed for the description and comparison of different streams. l The chronological sequence of occurrence of the flow is masked in the flow-duration curve. A discharge of say 1000 m3/s in a stream will have the same percentage Pp whether it has occurred in January or June. This aspect, a serious handicap, must be kept in mind while interpreting a flowduration curve. Fig. 5.9 Reservoir Regulation Effect l The flow-duration curve plotted on a log-log paper (Fig. 5.10) is useful in comparing the flow characteristics of different streams. A steep slope of the curve indicates a stream with a highly variable discharge. On the other hand, a flat slope indicates a slow response of the catchment to the

Fig. 5.10 Flow Duration Curve—Example 5.8

Runoff

165

rainfall and also indicates small variability. At the lower end of the curve, a flat portion indicates considerable base flow. A flat curve on the upper portion is typical of river basins having large flood plains and also of rivers having large snowfall during a wet season. Flow-duration curves find considerable use in water resources planning and development activities. Some of the important uses are: 1. In evaluating various dependable flows in the planning of water resources engineering projects 2. Evaluating the characteristics of the hydropower potential of a river 3. Designing of drainage systems 4. In flood-control studies 5. Computing the sediment load and dissolved solids load of a stream 6. Comparing the adjacent catchments with a view to extend the streamflow data. EXAMPLE 5.8 The daily flows of a river for three consecutive years are shown in Table 5.7. For convenience the discharges are shown in class intervals and the number of days the flow belonged to the class is shown. Calculate the 50 and 75% dependable flows for the river. SOLUTION: The data are arranged in descending order of class value. In Table 5.7, column 5 shows the total number of days in each class. Column 6 shows the cumulative total of column 5, i.e. the number of days the flow is equal to or greater than the class interval. This gives the value of m. The percentage probability Pp the probability of flow in the class interval being equalled or exceeded is given by Eq. (5.28), m Pp = ´ 100% ( N + 1) Table 5.7 Calculation of Flow Duration Curve from Daily Flow Data— Example 5.8 Daily mean No. of days flow in each discharge class interval (m3/s) 1961–62 1962–63 1963–64 1 140–120.1 120–100.1 100–80.1 80–60.1 60–50.1 50–40.1 40–30.1 30–25.1 25–20.1 20–15.1 15–10.1 10–5.1 Total

Total of columns 2, 3, 4 1961–64

Pp = æ m ö Cumulative çè N + 1 ÷ø Total m ´ 100%

2

3

4

5

6

0 2 12 15 30 70 84 61 43 28 15 5 365

1 7 18 32 29 60 75 50 45 30 18 — 365

5 10 15 15 45 64 76 61 38 25 12 — 366

6 19 45 62 104 194 235 172 126 83 45 5 N = 1096

6 25 70 132 236 430 665 837 963 1046 1091 1096

7 0.55 2.28 6.38 12.03 21.51 39.19 60.62 76.30 87.78 95.35 99.45 99.91

166 Engineering Hydrology In the present case N = 1096. The smallest value of the discharge in each class interval is plotted against Pp on a log-log paper (Fig. 5.10). From this figure Q50 = 50% dependable flow = 35 m3/s and Q75 = 75% dependable flow = 26 m3/s.

5.6 FLOW-MASS CURVE The flow-mass curve is a plot of the cumulative discharge volume against time plotted in chronological order. The ordinate of the mass curve, V at any time t is thus t

V = ò Q dt

(5.29)

t0

where t0 is the time at the beginning of the curve and Q is the discharge rate. Since the hydrograph is a plot of Q vs t, it is easy to see that the flow–mass curve is an integral curve (summation curve) of the hydrograph. The flow–mass curve is also known as Rippl’s mass curve after Rippl (1882) who suggested its use first. Figure 5.9 shows a typical flow–mass curve. Note that the abscissa is chronological time in months in this figure. It can also be in days, weeks or months depending on the data being analysed. The ordinate is in units of volume in million m3. Other units employed for ordinate include m3/s day (cumec day), ha.m and cm over a catchment area. dV The slope of the mass curve at any point represents = Q = rate of flow at that dt instant. If two points M and N are connected by a straight line, the slope of the line represents the average rate of flow that can be maintained between the times tm and tn if a reservoir of adequate storage is available. Thus the slope of the line AB joining the starting point and the last points of a mass curve represents the average discharge over the whole period of plotted record.

Calculation of Storage Volume Consider a reservoir on the stream whose mass curve is plotted in Fig. 5.11. If it is assumed that the reservoir is full at the beginning of a dry period, i.e. when the inflow rate is less than the withdrawal (demand) rate, the maximum amount of water drawn from the storage is the cumulative difference between supply and demand volumes from the beginning of the dry season. Thus the storage required S is S = maximum of (SVD – S Vs)

Fig. 5.11 Fow–Mass Curve

Runoff

167

where VD = demand volume, VS = supply volume. The storage, S which is the maximum cumulative deficiency in any dry season is obtained as the maximum difference in the ordinate between mass curves of supply and demand. The minimum storage volume required by a reservoir is the largest of such S values over different dry periods. Consider the line CD of slope Qd drawn tangential to the mass curve at a high point on a ridge. This represents a constant rate of withdrawal Qd from a reservoir and is called demand line. If the reservoir is full at C (at time tc) then from point C to E the demand is larger than the supply rate as the slope of the flow–mass curve is smaller than the demand line CD. Thus the reservoir will be depleting and the lowest capacity is reached at E. The difference in the ordinates between the demand line CD and a line EF drawn parallel to it and tangential to the mass curve at E (S1 in Fig. 5.11) represents the volume of water needed as storage to meet the demand from the time the reservoir was full. If the flow data for a large time period is available, the demand lines are drawn tangentially at various other ridges (e.g. C¢ D¢ in Fig. 5.11) and the largest of the storages obtained is selected as the minimum storage required by a reservoir. Example 5.9 explains this use of the mass curve. Example 5.10 indicates, storage calculations by arithmetic calculations by adopting the mass-curve principle. EXAMPLE 5.9 The following table gives the mean monthly flows in a river during 1981. Calculate the minimum storage required to maintain a demand rate of 40 m3/s. Month

Jan Fcb Mar Apr May June July Aug Sept Oct Nov Dec

Mean Flow (m3/s) 60

45

35

25

15

22

50

80

105

90

80

70

SOLUTION: From the given data the monthly flow volume and accumulated volumes and calculated as in Table 5.8. The actual number of days in the month are used in calculating of the monthly flow volume. Volumes are calculated in units of cumec. day (= 8.64 ´ 104). Table 5.8 Calculation of Mass Curve—Example 5.9 Month

Jan Feb Mar April May June July Aug Sep Oct Nov Dec

Mean flow (m3/s)

60 45 35 25 15 22 50 80 105 90 80 70

Monthly flow volume (cumec-day)

Accumulated volume (cumec-day)

1860 1260 1085 750 465 660 1550 2480 3150 2790 2400 2170

1860 3120 4205 4955 5420 6080 7630 10,110 13,260 16,050 18,450 20,620

A mass curve of accumulated flow volume against time is plotted (Fig. 5.12). In this figure all the months are assumed to be of average duration of 30.4 days. A demand line

168 Engineering Hydrology with slope of 40 m3/s is drawn tangential to the hump at the beginning of the curve; line AB in Fig. 5.12. A line parallel to this line is drawn tangential to the mass curve at the valley portion; line A¢B¢. The vertical distance S 1 between these parallel lines is the minimum storage required to maintain the demand. The value of S1 is found to be 2100 cumec. Days = 181.4 million m3.

EXAMPLE 5.10 Work out the Example 5.9 through arithmetic calculation without the use of mass curve. What is the maximum constant demand that can be sustained by this river?

Fig. 5.12 Flow-Mass Curve—Example 5.9

Table 5.9 Calculation of Storage—Example 5.9 Month

Jan Feb Mar Apr May Jun July Aug Sept Oct Nov Dec

Mean inflow rate (m3/s)

Inflow Demand Demand volume rate volume (cumec. (m3/s) (cumec. day) day)

60 1860 45 1260 35 1085 25 750 15 465 22 660 50 1550 80 2480 105 3150 90 2790 80 2400 70 2170 Monthly mean = 1718.3

40 40 40 40 40 40 40 40 40 40 40 40

1240 1120 1240 1200 1240 1200 1240 1240 1200 1240 1200 1240

Departure Cum. [co1. 3excess col. 5) demand volume (cumec. day) 620 140 –155 –450 –775 –540 310 1240 1950 1550 1200 930

–155 –605 –1380 –1920

Cum. excess inflow volume (cumec. day) 620 760

310 1550 3500 5050 6250 7180

Runoff

169

SOLUTION: The inflow and demand volumes of each month are calculated as in Table 5.9. Column 6 indicating the departure of the inflow volume from the demand. The negative values indicate the excess of demand over the inflow and these have to be met by the storage. Column 7 indicates the cumulative excess demand (i.e., the cumulative excess negative departures). This column indicates the depletion of storage, the first entry of negative value indicates the beginning of dry period and the last value the end of the dry period. Col. 8 indicates the filling up of storage and spill over (if any). Each dry period and each filling up stage is to be calculated separately as indicated in Table 5.9. The maximum value in Col. 7 represents the minimum storage necessary to meet the demand pattern. In the present case, there is only one dry period and the storage requirement is 1920 cumec.day. Note that the difference between this value and the value of 2100 cumec.day obtained by using the mass curve is due to the curvilinear variation of inflow volumes obtained by drawing a smooth mass curve. The arithmetic calculation assumes a linear variation of the mass curve ordinates between two adjacent time units. [Note: It is usual to take data pertaining to a number of N full years. When the analysis of the given data series of length N causes the first entry in Col. 7 to be a negative value and the last entry is also a negative value, then the calculation of the maximum deficit may pose some confusion. In such cases, repeating the data sequence by one more data cycle of N years in continuation with the last entry would overcome this confusion. (See Sec. 5.7, item 2.) There are many other combinations of factors that may cause confusion in interpretation of the results and as such the use of Sequent Peak Algorithm described in Sec. 5.7 is recommended as the foolproof method that can be used with confidence in all situations.] Column 8 indicates the cumulative excess inflow volume from each demand withdrawal from the storage. This indicates the filling up of the reservoir and volume in excess of the provided storage (in the present case 1920 cumec.day) represent spill over. The calculation of this column is necessary to know whether the reservoir fills up after a depletion by meeting a critical demand and if so, when? In the present case the cumulative excess inflow volume will reach +1920 cumec.day in the beginning of September. The reservoir will be full after that time and will be spilling till end of February. Average of the inflow volume per month = Annual inflow volume/12 = average monthly demand that can be sustained by this river = 1718.33 cumec.day. Calculation of Maintainable Demand The converse problem of determining the maximum demand rate that can be maintained by a given storage volume can also be solved by using a mass curve. In this case tangents are drawn from the “ridges” of the mass curves across the next “valley” at various slopes. The demand line that requires just the given storage (u1 v1 in Fig. 5.13) is the proper demand that can be sustained by the reservoir in that dry period. Similar demand lines are drawn at other “valleys” in the mass curve (e.g. u2 v2 and the demand rates determined. The smallest of the various demand rates thus found denotes the maximum firm demand that can be sustained by the given storage. It may be noted that this problem involves a trial-and-error procedure for its solution. Example 5.10 indicates this use of the mass curve. The following salient points in the use of the mass curve are worth noting: l The vertical distance between two successive tangents to a mass curve at the ridges (points v1 and u2 in Fig. 5.13) represent the water “wasted” over the spillway. l A demand line must intersect the mass curve if the reservoir is to refill. Nonintersection of the demand line and mass curve indicates insufficient inflow.

170 Engineering Hydrology

Fig. 5.13 Determination of Maintainable Demand EXAMPLE 5.11 Using the mass curve of Example 5.9 obtain the maximum uniform rate that can be maintained by a storage of 3600 m3/s days. SOLUTION: An ordinate XY of magnitude 3600 Cumec-days is drawn in Fig. 5.12 at an approximate lowest position in the dip of the mass curve and a line passing through Y and tangential to the “hump” of the mass curve at C is drawn (line CYD in Fig. 5.12). A line parallel to CD at the lowest position of the mass curve is now drawn and the vertical interval between the two measured. If the original guess location of Y is correct, this vertical distance will be 3600 m3/s day. If not, a new location for Y will have to be chosen and the above procedure repeated. The slope of the line CD corresponding to the final location of XY is the required demand rate. In this example this rate is found to be 50 m3/s. Variable Demand In the examples given above a constant demand rate was assumed to simplify the problem. In practice, it is more likely that the demand rate varies with time to meet various end uses, such as irrigation, power and water-supply needs. In such cases a mass curve of demand, also known as variable use line is prepared and superposed on the flow–mass curve with proper matching of time. For example, the demand for the month of February must be against the inflow for the same month. If the reservoir is full at first point of intersection of the two curves, the maximum intercept between the two curves represents the needed storage of the reservoir (Fig. 5.14). Such a plot is sometimes known as regulation diagram of a reservoir. Fig. 5.14 Variable Use Line

Runoff

171

In the analysis of problems related to the reservoirs it is necessary to account for evaporation, leakage and other losses from the reservoir. These losses in the volume of water in a known interval of time can either be included in demand rates or deducted from inflow rates. In the latter method, which is generally preferred, the mass curve may have negative slopes at some points. Example 5.12 gives an arithmetic calculation procedure for calculating storage under variable demand.

EXAMPLE 5.12 For a proposed reservoir the following data were calculated. The prior water rights required the release of natural flow or 5 m3/s, whichever is less. Assuming an average reservoir area of 20 km2, estimate the storage required to meet these demands. (Assume the runoff coefficient of the area submerged by the reservoir = 0.5.) Month Jan Feb Mar April May June July Aug Sept Oct Nov Dec

Mean flow (m3/s)

Demand (million m3)

25 20 . 15 10 4 9 100 108 80 40 30 30

22.0 23.0 24.0 26.0 26.0 26.0 16.0 16.0 16.0 16.0 16.0 22.0

Monthly evaporation Monthly rainfall (cm) (cm) 12 13 17 18 20 16 12 12 12 12 11 17

2 2 1 1 1 13 24 19 19 1 6 2

SOLUTION: Use actual number of days in a month for calculating the monthly flow and an average month of 30.4 days for prior right release. Prior right release = 5 ´ 30.4 ´ 8.64 ´ 104 = 13.1 Mm3 when Q > 5.0 m3/s. E Evaporation volume = ´ 20 ´ 106 = 0.2 E Mm3 100 P Rainfall volume = ´ (1 – 0.5) ´ 20 = 0.1 P Mm3 100 Inflow volume: I ´ (No. of days in the month) ´ 8.64 ´ 104 m3 The calculations are shown in Table 5.6 and the required storage capacity is 64.5 Mm3. The mass-curve method assumes a definite sequence of events and this is its major drawback. In practice, the runoff is subject to considerable time variations and definite sequential occurrences represent only an idealized situation. The mass-curve analysis is thus adequate for small projects or preliminary studies of large storage projects. The latter ones require sophisticated methods such as time-series analysis of data for the final design.

5.7 SEQUENT PEAK ALGORITHM The mass curve method of estimating the minimum storage capacity to meet a specified demand pattern, described in the previous section has a number of different forms of use in its practical application. However, the following basic assumptions are made in all the adaptations of the mass-curve method of storage analysis.

172 Engineering Hydrology Table 5.10 Calculation of Reservoir Storage-Example 5.12 Month

InWithdrawal Total Depar- Cum. Cum. flow Demand Prior Evapo- Rain- withture Excess Excess volume (Mm3) rights ration fall drawal demand flow (Mm3) (Mm3) (Mm3) (Mm3) (3+4+ volume 5+6) (Mm3) (Mm3) (Mm3) (Mm3)

1

2

3

4

5

6

Jan Feb Mar Apr May June July Aug Sept Oct Nov Dec

67.0 48.4 40.2 25.9 10.7 23.3 267.8 289.3 207.4 107.1 77.8 80.4

22.0 23.0 24.0 26.0 26.0 26.0 16.0 16.0 16.0 16.0 16.0 22.0

13.1 13.1 13.1 13.1 10.7 13.1 13.1 13.1 13.1 13.1 12.1 13.1

2.4 2.6 3.4 3.6 4.0 3.2 2.4 2.4 2.4 2.4 2.2 3.4

–0.2 –0.2 –0.1 –0.1 –0.1 –1.3 –2.4 –1.9 –1.9 –0.1 –0.6 –0.2

7

8

37.3 +29.7 38.5 +9.9 40.4 –0.2 42.6 –16.7 40.6 –29.9 41.0 –17.7 29.1 +238.7 29.6 259.7 29.6 177.8 31.4 75.7 30.7 47.1 38.3 42.1

9

10

— — –0.2 –16.9 –46.8 –64.5 —

29.7 39.6 — — 238.7 498.4 676.2 751.9 799.0 841.1

If N years of data are available, the inflows and demands are assumed to repeat in cyclic progression of N year cycles. It is to be noted that in historical data this leads to an implicit assumption that future flows will not contain a more severe drought than what has already been included in the data. l The reservoir is assumed to be full at the beginning of a dry period. Thus, while using the mass curve method the beginning of the dry period should be noted and the minimum storage required to pass each drought period calculated. Sometimes, for example in Problem 5.7, it may be necessary to repeat the given data series of N years sequentially for a minimum of one cycle, i.e. for additional N years, to arrive at the desired minimum storage requirement. The mass curve method is widely used for the analysis of reservoir capacity-demand problems. However, there are many variations of the basic method to facilitate graphical plotting, handling of large data, etc. A variation of the arithmetical calculation described in Examples 5.10 and 5.12 called the sequent peak algorithm is particularly suited for the analysis of large data with the help of a computer. This procedure, first given by Thomas (1963), is described in this section. Let the data be available for N consecutive periods not necessarily of uniform length. These periods can be year, month, day or hours depending upon the problem. In the ith period let xi = inflow volume and Di = demand volume. The surplus or deficit of storage in that period is the net-flow volume given by Net-flow volume = Inflow volume – Outflow volume = xi – Di In the sequent peak algorithm a mass curve of cumulative net-flow volume against chronological time is used. This curve, known as residual mass curve (shown typically in Fig. 5.15), will have peaks (local maximums) and troughs (local minimums). l

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Fig. 5.15 Residual Mass Curve—Definition Sketch for Sequent Peak Algorithm For any peak P, the next following peak of magnitude greater than P, is called a sequent peak. Using two cycles of N periods, where N is the number of periods of the data series, the required storage volume is calculated by the following procedure: 1. Calculate the cumulative net-flow volumes, viz. t

2. 3. 4. 5. 6.

å(xi – Di)

for t = 1, 2, 3 …, 2 N Locate the first peak P1 and the sequent peak P2 which is the next peak of greater magnitude than P1 (Fig. 5.15). Find the lowest trough T1 between P1 and P2 and calculate (P1 – T1). Starting with P2 find the next sequent peak P3 and the lowest through T2 and calculate (P2 – T2). Repeat the procedure for all the sequent peaks available in the 2N periods, i.e. determine the sequent peak Pj, the corresponding Tj and the jth storage (Pj – TJ) for all j values. The required reservoir storage capacity is S = maximum of (Pj – Tj) values

EXAMPLE 5.13 The average monthly flows into a reservoir in a period of two consecutive dry years 1981-82 and 1982-83 is given below. Month

Mean monthly flow (m3/s)

Month

Mean monthly flow (m3/s)

1981— June July Aug Sept Oct Nov Dec 1982— Jan Feb March April May

20 60 200 300 200 150 100 80 60 40 30 25

1982— June July Aug Sept Oct Nov Dec 1983—Jan Feb March April May

15 50 150 200 80 50 110 100 60 45 35 30

174 Engineering Hydrology If a uniform discharge at 90 m3/s is desired from this reservoir calculate the minimum storage capacity required.

SOLUTION: The data is for 2 years. As such, the sequent peak calculations are performed for 2 ´ 2 = 4 years. The calculations are shown in Table 5.11. Scanning the cumulative net-flow volume values (Col. 7) from the start, the first peak P1 is identified as having a magnitude of 12,200 cumec. day which occurs in the end of the seventh month. The sequent peak P2 is the peak next to P1 and of magnitude higher Table 5.11 Sequent Peak Algorithm Calculations—Example 5.13 S.l. No.

Month Mean inflow rate (m3/s)

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33

June July Aug. Sept. Oct. Nov. Dec. Jan. Feb. March April May June July Aug. Sept. Oct. Nov. Dec. Jan. Feb. March April May June July Aug. Sept. Oct. Nov. Dec. Jan. Feb.

20 60 200 300 200 150 100 80 60 40 30 25 15 50 150 200 80 50 110 100 60 45 35 30 20 60 200 300 200 150 100 80 60

Inflow Demand Demand volume rate volume xi (m3/s) Di (cumec. (cumec. day) day) 600 1860 6200 9000 6200 4500 3100 2480 1680 1240 900 775 450 1550 4650 6000 2480 1500 3410 3100 1680 1395 1050 930 600 1860 6200 9000 6200 4500 3100 2480 1680

90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90

2700 2790 2790 2700 2790 2700 2790 2790 2520 2790 2700 2790 2700 2790 2790 2700 2790 2700 2790 2790 2520 2790 2700 2790 2700 2790 270 2700 2790 2700 2790 2790 2520

Net-flow volume (xi – Di) (cumec. day)

Cumula- Remark tive netflow volume S(xi – Di) (cumec. day)

–2100 –2,100 I Cycle –930 –3,030 +3410 +380 6300 6,680 3410 10,090 1800 11,890 310 12,200* First peak –310 11,890 P1 –840 11,050 –1550 9,500 –1800 7,700 –2015 5,685 –2250 3,435 –1240 2,195 1860 4,055 3300 7,355 –310 7,045 –1200 5,845 620 6,465 310 6,775 –840 5,935 –1395 4,540 –1650 2,890 –1860 1,030 –2100 1,070 II Cycle –930 –2,000* Lowest 3410 1,410 trough T1 6300 7,710 between P1 3410 11,120 and P2 1800 12,920 310 13,230* Sequent –310 12,920 Peak P2 –840 12,080 (Contd.)

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Table 5.11 (Contd.) S.l. No.

Month Mean inflow rate (m3/s)

34 35 36 37 38 39 40 41 42 43 44 45 46 47 48

March April May June July Aug. Sept. Oct. Nov. Dec. Jan. Feb. March April May

Inflow Demand Demand volume rate volume (m3/s) Di xi (cumec. (cumec. day) day)

40 30 25 15 50 150 200 80 50 110 100 60 45 38 30

1240 900 775 450 1550 4650 6000 2480 1500 3410 3100 1680 1395 1050 930

90 90 90 90 90 90 90 90 90 90 90 90 90 90 90

2790 2700 2790 2700 2790 2790 2700 2790 2700 2790 2790 2520 2790 2700 2790

Net-flow volume (xi – Di) (cumec. day) –1550 –1800 –2015 –2250 –1240 1860 3300 –310 –1200 620 310 –840 –1395 –1650 –1860

Cumula- Remark tive netflow volume S(xi – Di) (cumec. day) 10,530 8,730 6,715 4,465 3,225 5,085 8,385 8,075 6,875 7,495 7,805 6,965 5,570 3,920 2,060

(Note: Since N = 2 years the data is run for 2 cycles of 2 years each.) than 12,200. This P2 is identified as having a magnitude of 13,230 cumec. day and occurs in the end of the 31st month from the start. Between P1 and P2 the lowest trough T1 has a magnitude of (–2,000) cumec. day and occurs at the end of the 26th month. In the present data run for two cycles of total duration 4 years, no further sequent peak is observed. P1 – T1 = 12,000 – (–2000) = 14,200 cumec. day Since there is no second trough, The required minimum storage = maximum of (Pj – Tj) values = (P1 – T1) = 14,200 cumec. day

5.8

DROUGHTS

In the previous sections of this chapter the variability of the stream flow was considered in the flow duration curve and flow mass curve. However, the extremes of the stream flow as reflected in floods and droughts need special study. They are natural disasters causing large scale human suffering and huge economic loss and considerable effort is devoted by the world over to control or mitigate the ill effects of these two hydrological extremes. The various aspects of floods are discussed in Chapters 7 and 8. The topic of drought, which is not only complex but also region specific is discussed, rather briefly, in this section. The classification of droughts and the general nature of drought studies are indicated with special reference to the Indian conditions. For further details the reader is referred to References 1, 2, 4 and 6.

Definition and Classification Drought is a climatic anomaly characterized by deficit supply of moisture. This may result from subnormal rainfall over large regions causing below normal natural avail-

176 Engineering Hydrology ability of water over long periods of time. Drought phenomenon is a hydrological extreme like flood and is a natural disaster. However, unlike floods the droughts are of the creeping kind; they develop in a region over a length of time and sometimes may extend to continental scale. The consequences of droughts on the agricultural production, hydropower generation and the regional economy in general is well known. Further, during droughts the quality of available water will be highly degraded resulting in serious environmental and health problems. Many classifications of droughts are available in literature. The following classification into three categories proposed by the National Commission on Agriculture (1976) is widely adopted in the country: l Meteorological drought: It is a situation where there is more than 25% decrease in precipitation from normal over an area. l Hydrological drought: Meteorological drought, if prolonged, results in hydrological drought with marked depletion of surface water and groundwater. The consequences are the drying up of tanks, reservoirs, streams and rivers, cessation of springs and fall in the groundwater level. l Agricultural drought: This occurs when the soil moisture and rainfall are inadequate during the growing season to support healthy crop growth to maturity. There will be extreme crop stress and wilt conditions. Meteorological Drought The India Meteorological Department (IMD) has adopted the following criteria for sub-classification of meteorological droughts. A meteorological sub-division is considered to be affected by drought if it receives a total seasonal rainfall less than that of 75% of the normal value. Also, the drought is classified as moderate if the seasonal deficiency is between 26% and 50%. The drought is said to be severe if the deficiency is above 50% of the normal value. Further, a year is considered to be a drought year in case the area affected by moderate or severe drought either individually or collectively is more than 20% of the total area of the country. If the drought occurs in an area with a probability 0.2 £ P £ 0.4 the area is classified as drought prone area, if the probability of occurrence of drought at a place is greater than 0.4, such an area is called as chronically drought prone area. Further, in India the meteorological drought is in general related to the onset, breaks and withdrawal times of monsoon in the region. As such, the prediction of the occurrence of drought in a region in the country is closely related to the forecast of deficient monsoon season and its distribution. Accurate forecast of drought, unfortunately, is still not possible. Hydrological Drought From a hydrologist’s point of view drought means below average values of stream flow, contents in tanks and reservoirs, groundwater and soil moisture. Such a hydrological drought has four components: (a) Magnitude (= amount of deficiency) (b) Duration (c) Severety (= cumulative amount of deficiency) (d) Frequency of occurrence

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The beginning of a drought is rather difficult to determine as drought is a creeping phenomenon. However, the end of the drought when adequate rainfall saturates the soil mass and restores the stream flow and reservoir contents to normal values is relatively easy to determine. In the studies on hydrological drought different techniques have to be adopted for study of (i) surface water deficit, and (ii) groundwater deficit. The surface water aspect of drought studies is essentially related to the stream and the following techniques are commonly adopted: (a) Low-flow duration curve (b) Low-flow frequency analysis and (c) Stream flow modelling. Such studies are particularly important in connection with the design and operation of reservoirs, diversion of stream flow for irrigation, power and drinking water needs; and in all activities related to water quality. Agricultural Drought Deficiency of rainfall has been the principal criteria for defining agricultural drought. However, depending on whether the study is at regional level, crop level or plant level there have been a variety of definitions. Considering the various phases of growth of a crop and its corresponding water requirements, the time scale for water deficiency in agricultural drought will have to be much smaller than in hydrological drought studies. Further, these will be not only regional specific but also crop and soil specific. An aridity index (AI) is defined as PET - AET AI = ´ 100 (5.30) PET where PET = Potential evapotranspiration and AET = Actual evapotranspiration. In this AI calculation, AET is calculated according to Thornthwite’s water balance technique, taking in to account PET, actual rainfall and field capacity of the soil. It is common to calculate AI on weekly or bi-weekly basis. AI is used as an indicator of possible moisture stress experienced by crops. The departure of AI from its corresponding normal value, known as AI anomaly, represents moisture shortage. Based on AI anomaly, the intensity of agricultural drought is classified as follows: AI anomaly

Severity class

Zero or negative 1 –25 26 –50 > 50

Non-arid Mild arid Moderate arid Severe arid

In addition to AI index, there are other indices such as Palmer index (PI) and Moisture availability index (MAI) which are used to characterize agricultural drought. IMD produces aridity index (AI) anomaly maps of India on a bi-weekly basis based on data from 210 stations representing different agro-climatic zones in the country. These are useful in planning and management of agricultural operations especially in the drought prone areas. Remote sensing techniques using imageries offer excellent possibilities for monitoring agricultural drought over large areas.

178 Engineering Hydrology

Drought Management The causes of drought are essentially due to temporal and spatial aberrations in the rainfall, improper management of available water and lack of soil and water conservation. Drought management involves development of both short-term and longterm strategies. Short-term strategies include early warning, monitoring and assessment of droughts The long-term strategies aim at providing drought mitigating measures through proper soil and water conservation, irrigation scheduling and cropping patterns. Figure 5.16 shows some impacts and possible modifications of various drought components. The following is a list of possible measures for making drought prone areas less vulnerable to drought associated problems:

Fig. 5.16 Impact and Possible Modification of Drought Components Creation of water storages through appropriate water resources development Inter-basin transfer of surface waters from surplus water areas to drought prone areas l Development and management of ground water potential l Development of appropriate water harvesting practices l In situ soil moisture conservation measures l Economic use of water in irrigation through practices such as drip irrigation, sprinkler irrigation, etc. l Reduction of evaporation from soil and water surfaces l Development of afforestation, agro-forestry and agro-horticulture practices l Development of fuelwood and fodder l Sand dune stabilization Drought-proofing of a region calls for integrated approach, taking into account the multi-dimensional interlinkages between various natural resources, environment and local socio-economic factors. Salient features of water harvesting, which forms an important component in modification of drought components is described in the next sub-section. l l

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Water Harvesting Water harvesting is a general term to include all systems that concentrate, collect and store runoff from small catchments for later use in smaller user areas. FAO defines water harvesting as, “Water harvesting is defined as the process of collecting and concentrating runoff water from a runoff area into a run-on area, where the collected water is either directly applied to the cropping area and stored in the soil profile for immediate use by the crop, i.e. runoff farming, or stored in an on-farm water reservoir for future productive uses, i.e. domestic use, livestock watering, aquaculture and irrigation.” The collected water can also be used for groundwater recharge and storage in the aquifer, i.e. recharge enhancement. As a general rule the catchment area from which the water is drawn is larger than the command area, where it is collected and used. The ratio of catchment, to command is inversely related to the amount and intensity of rainfall, the impermeability of soil, and the slope of the land on which it falls. Water harvesting is essentially a traditional system used since many centuries, now being made over to meet present-day needs. Depending upon the nature of collecting surface and type of storages water harvesting is classified into several categories as mentioned in Fig. 5.17.

Fig. 5.17 Classification of Water Harvesting Techniques Roof Top Water Harvesting The productive utilization of rain water falling on roof-tops of structures is known as Roof Top Water Harvesting (RTWH). In urban areas the roof tops are usually impervious and occupy considerable land area. Also, generally the municipal water supply is likely to be inadequate, inefficient or unreliable. In such situations, collection of runoff from roof tops of individual structures and storing them for later use has been found to be very attractive and economical proposition in many cases. Inadequacy of water availability and cost of supply has made many industries and large institutions in urban areas situated in arid and semiarid regions to adopt RTWH systems in a big way. Factors like water quality, methods for efficient and economical collection and storage are some factors that have to be worked out in designing an efficient system to meet specific needs. The cost of adequate size storage is, generally, a constraint in economical RTWH design. In many cases, water collected from roof top is used for recharging the ground water. Charac-

180 Engineering Hydrology teristics of the rainfall at the place, such as intensity, duration, nature of the rainfall season, average number of rainy days, determine the design of the RTWH design. Micro Catchment System (Within the Field) of Rainwater Harvesting In this system the catchment is a small area which is not put for any productive purpose. The catchment length is usually between 1 and 30 metres and the overland flow from this during a storm is harvested by collecting and delivering it to a small cultivated plot. The ratio of catchment to the cultivated area is usually 1:1 to 3:1 and the runoff is stored in soil profile. Normally there will be no provision for overflow. Rainwater harvesting in Micro catchments is sometimes referred to as WithinField Catchment System. Typical examples of such Rainwater harvesting in micro catchments are: l Negarim Micro Catchments (for trees) l Contour Bunds (for trees) l Contour Ridges (for crops) l Semi-Circular Bunds (for range and fodder) Negarim micro catchment technique was originally developed in Israel; the word Negarim is derived from Hebrew word Neger meaning runoff. This technique consists of dividing the catchments into a large number of micro catchments in a diamond pattern along the slope. Each micro catchment is of square shape with a small earthen bunds at its boundary and an infiltration pit is provided at the lowest corner as shown in Fig. 5.18. The pit is the cultivated area and usually a tree is grown in the pit. This arrangement of micro catchments of sizes 10 m2 to 100 m2, has been found Fig. 5.18 Micro Catchment System: Negarim Micro to be very beneficial in arid and semiarid areas where rainfall can be as low as 150 mm. Catchment for Trees Macro Catchment System (Within the Field) of Rainwater Harvesting This system is designed for slightly larger catchment areas wherein overland flow and rill flow is collected behind a bund and allowed to be stored in the soil profile through infiltration. The catchment is usually 30 to 200 m long and the ratio of catchment to cultivated area is in the range 2 :1 to 10:1. Typical arrangement consists of one row or two staggered rows of trapezoidal bunds with wing walls. Contour bunds made of piled up stones is also used in this system. It is usual to provide overflow arrangements for disposing of the excess runoff water. Infiltration area behind the bunds is used to grow crops. Floodwater Farming (Floodwater Harvesting) This system is used for larger catchments and the flow in the drainage is harvested. The catchment areas are several kilometres long and the ratio of catchment to command is larger than 10:1. Two sub-systems mentioned below are in common use: 1. Water Harvesting using Storage Structures 2. Water Harvesting through Spreading of Water over Command

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Storage Structures Systems Small storage structures are built across

the drainage to store a part of the runoff. While the stored surface water would serve as a source of utilisable water to the community for some time the infiltration from this water body would provide valuable recharge to the ground water. The commonly used structures are Check dams and Nalabunds. These structures have the additional advantage of arresting erosion products from the catchment. Further, these structures prevent the deepening and widening of gullies. The check dams usually have a masonry overflow spillway and the flanks can be of either masonry construction or of earthen embankment. They are constructed on lower order streams (up to 3) with median slopes. Generally check dams are proposed where water table fluctuations are high and the stream is influent. Nalabunds are structures constructed across nalas (streams) for impounding runoff flow to cause a small storage. Increased water percolation and improving of soil moisture regime are its main objective. Nalabunds are of small dimension and are constructed by locally available material, usually an earthen embankment. In a Nalabund the spillway is normally a stone lined or rock cut steep channel taking off from one of the ends of the bund at appropriate level. Structures similar to a nalabund but of larger dimension are known as percolation tanks. Nalabunds and percolation tanks are constructed in flat reach of a stream with slopes less than 2%. The irrigation tanks of south India are also sometimes termed as water harvesting structures. Tanks on local streams form a significant source of irrigation in states of Andhra Pradesh, Karnataka, Maharashtra and Tamil Nadu. These are small storage structures formed by earthen bunds to store runoff, of a small stream. The embankment, surplus weir and a sluice outlet form the essential component of a tank. The tank system in a region, which can be a group of independent tanks or a set of tanks in cascade, form an important source of surface water for domestic use, drinking water for life stock, agriculture for growing food and fodder and recharge of subsurface aquifers.

Spreading of Water In this method a diversion across the drainage would cause the runoff to flow on to the adjacent land. Appropriate bunds either of rock or of earth would cause spreading the water over the command. The spread water infiltrates into the soil and is retained as soil moisture and this is used for growing crops. Provision for overflow spillway at the diversion structure, to pass excess water onto the downstream side of the diversion structure, is an important component of the diversion structure. General: The specific aspects related to the design of water harvesting structures depends upon the rainfall in the region, soil characteristics and terrain slope. It is usual to take up water harvesting activity at a place as a part of intergraded watershed management programme. Norms for estimating recharge from water harvesting structures are given in Sec. 9.13 of Chapter 9. The water harvesting methods described above are particularly useful in dry land agriculture and form important draught management tool. Community participation in construction and management of water harvesting structure system is essential for economical and sustainable use of the system. Rehabilitation of old irrigation tanks through de-silting to bring it back to its original capacity is now recognized as a feasible and desirable activity in drought proofing of a region.

182 Engineering Hydrology

Droughts in India Even though India receives a normal annual precipitation of 117 cm, the spatial and temporal variations lead to anomalies that lead to floods and droughts. Consequently droughts have been an everpresent feature of the country. While drought has remained localized in some part of the country in most of the years they have become wide spread and severe in some years. In the past four decades, wide spread and severe droughts have occurred in the years 1965–66, 1971–73, 1979–80, 1982–83, 1984– 87, 1994–96, 1999–2000, 2001–02. These droughts affected the agricultural production and the economy significantly and caused immense hardship and misery to a very large population. Since 1875 till 2004, India faced 29 drought years; the 1918 being the worst year in which about 70% of the country was affected by drought. Analysis of records since 1801 reveals that nearly equal number droughts occurred in 19th century and in 20th century and that there is a lower number of occurrences in the second quarter of both centuries. It has been estimated that nearly one third of the area of the country (about 1 M ha) is drought prone. Most of the drought prone areas lie in the states of Rajasthan, Karnataka, Andhra Pradesh, Maharashtra, Gujarat and Orissa. Roughly 50% of the drought prone area of the country lies in Deccan plateau. Further, while Rajasthan has a return period of about 2 years for severe droughts it is about 3 years in the Deccan plateau region. It is difficult to estimate the economic losses of drought, as it is a creeping phenomenon with wide spatial coverage. However, a wide spread drought in the country would cover agricultural areas of the order of 100 lakh ha and the consequential loss due to damaged crops could be of the order of Rs 5000 crores.

5.9 SURFACE WATER RESOURCES OF INDIA Surface Water Resources Natural (Virgin) Flow in a river basin is reckoned as surface resource of a basin. In view of prior water resources development activities, such as construction of storage reservoirs in a basin, assessment of natural flow is a very complex activity. In most of the basins of the country, water resources have already been developed and utilized to various extents through construction of diversion structures and storage reservoirs for purposes of irrigation, drinking water supply and industrial uses. These utilizations in turn produce return flows of varying extent; return flow being defined as the nonconsumptive part of any diversion returned back. Return flows to the stream from irrigation use in the basin are usually assumed to be 10% of the water diverted from the reservoir or diversion structure on the stream for irrigation. The return flows from diversions for domestic and industrial use is usually assumed as 80% of the use. The return flow to the stream from ground water use is commonly ignored. The natural flow in a given period at a site is obtained through water budgeting of observed flow, upstream utilization and increase in storage, evaporation and other consumptive uses and return flows. The surface and groundwater components are generally treated separately. Estimation of surface water resources of the country has been attempted at various times. Significant recent attempts are: l A.N. Khosla’s estimate (1949), based on empirical relationships, of total annual flow of all the river systems of the country as 1673 km3.

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CWC (1988), on the basis of statistical analysis of available data, and on rainfall–runoff relationships where flow data was meagre or not available, estimated the total annual runoff of the river systems of India as 1881 km3. l The National Commission for Integrated Water Resources Development (1999) used the then available estimates and data and assessed the total surface water resources of the country as 1952.87 km3 (say 1953 km3). It should be noted that the average annual natural (Virgin) flow at the terminal point of a river is generally taken as the surface water resources of the basin. But this resource is available with a probability of about 50% whereas it is customary to design irrigation projects with 75% dependability and domestic water supply projects for nearly 100% dependability. Obviously, the magnitude of water at higher values of dependability (say 75% and above) will be smaller than the average value. The total catchment area of all the rivers in India is approximately 3.05 million km2. This can be considered to be made up of three classes of catchments: 1. Large catchments with basin area larger than 20,000 km2; 2. Medium catchments with area between 20,000 to 2000 km2; and 3. Small catchments with area less than 2000 km2. Rao9 has estimated that large catchments occupy nearly 85% of the country’s total drainage area and produce nearly 85% of the runoff. The medium and minor catchments account for 7% and 8% of annual runoff volumes respectively. In the major river basin of the country two mighty rivers the Brahmaputra and the Ganga together constitute 71.5% of the total yield in their class and contribute 61% of the country’s river flow. Further, these two rivers rank eighth and tenth respectively in the list of the world’s ten largest rivers (Table 5.12). It is interesting to note that the ten rivers listed in Table 5.12 account for nearly 50% of the world’s annual runoff. l

Table 5.12 World’s Ten Largest Rivers Sl. No 1. 2. 3. 4. 5. 6. 7. 8. 9. 10.

River Amazon Platt Congo Orinoco Yangtze Mississippi Yenisei Brahmputra Mekong Ganga

Annual runoff (Billion m3) 6307 1358 1245 1000 927 593 550 510 500 493

According to an analysis of CWC, about 80% of average annual flow in the rivers of India is carried during monsoon months. This highlights the need for creating storages for proper utilization of surface water resources of the country. Another interesting aspect of Indian rivers is that almost all the rivers flow through more than one state, highlighting the need for inter-state co-operation in the optimum development of water resources.

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Utilizable Water Resources Utilizable water resources mean the quantum of water withdrawable from its place of natural occurrence. Withdrawal of water from a river depends on topographic conditions and availability of land for the stated project. As a result of various limitations such as to topography, environmental consideration, non-availability of suitable locations and technological shortcomings, it will not be possible to utilize the entire surface water resources of the country. Further, surface water storage structures, such as reservoirs, cause considerable loss by evaporation and percolation. Also, environmental considerations preclude total utilization or diversion of surface water resources of a basin. From these considerations, it is necessary to estimate the optimum utilizable surface runoff of the country for planning purposes. Normally, the optimum utilizable surface runoff of a basin will be around 70% of the total surface runoff potential of the basin. CWC in 1988 estimated the utilizable surface water resource of the country as 690.32 km3. The National Commission for Integrated Water Resources Development8 (1999) has adopted this value in preparing estimates of future water demand–supply scenarios up to the year 2050. Table 5.13 gives the basinwise distribution of utilizable surface water resource of the country. Table 5.13

Average Flow and Utilizable Surface Water Resource of Various Basins [Unit: km3/Year] (Source: Ref. 8]

S. River Basin No.

1. 2.

3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17.

Indus Ganga–Brahmaputra–Meghna Basin 2a Ganga sub-basin 2b Brahmaputra sub-basin and 2c Meghna (Barak) sub-basin Subarnarekha Brahmani–Baitarani Mahanadi Godavari Krishna Pennar Cauvery Tapi Narmada Mahi Sabarmati West flowing rivers of Kutchch and Saurashtra West flowing rivers south of Tapi East flowing rivers between Mahanadi and Godavari East flowing rivers between Godavari and Krishna

Surface water resources

Utilizable surface water resources

73.31

46

525.02 629.05 48.36 12.37 28.48 66.88 110.54 69.81 6.86 21.36 14.88 45.64 11.02 3.81 15.10 200.94 17.08 1.81

250.0 24.0 6.81 18.30 49.99 76.30 58.00 6.32 19.00 14.50 34.50 3.10 1.93 14.96 36.21 13.11 (Contd.)

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(Contd.) 18. East flowing rivers between Krishna and Pennar 19. East flowing rivers between Pennar and Cauvery 20. East flowing rivers south of Cauvery 21. Area North of Ladakh not draining into India 22. Rivers draining into Bangladesh 23. Rivers draining into Myanmar 24. Drainage areas of Andaman, Nicobar and Lakshadweep islands Total

3.63 9.98 6.48 0 8.57 22.43 0 1952.87

185

16.73 0 0 0 0 690.32

In the computation of utilizable water resources as 690 km3 it is assumed that adequate storage facility is available for balancing the monsoon flows into an average year round availability. The minimum storage required to achieve this is estimated as 460 km3 against the present estimated total available storage capacity of 253 km3. If more storage capacity could be developed carry-over from years of above normal rainfall to dry years would be possible. For comparison purposes, for about the same annual runoff the USA has storage of 700 km3. Utilizable Dynamic Groundwater Resources The total replenish-able groundwater resources of the country (dynamic) has been estimated by CGWB as 431.89 km3/year and the utilizable dynamic groundwater potential as 396 km3/year (details in Chapter 9, Section 9.12). Water Available from Return Flows Water used for a specific activity such as irrigation and domestic water supply includes consumptive and non-consumptive components. The non-consumptive component part of water use is returned back to hydrologic system either as surface flow or as addition to groundwater system or as soil moisture. However, due to economic and technological constraints and due to possibilities of diminished water quality, only a part of the return flow is recoverable for re-use. The utilizable return flow is an important component to be considered in the demand–supply analysis of utilizable water resources.

Total Water Requirement and Available Resources Scenario Total Water Requirement for Different Uses The estimated total water requirements, estimated by NCIWRD8, for the two scenarios and for various sectors at three future horizons are shown in Table 5.14. Irrigation would continue to have the highest water requirement (about 68% of total water requirement), followed by domestic water including drinking and bovine needs. Evaporation In water resources evaluation studies it is common to adopt a percentage of the live capacity of a reservoir as evaporation losses. The NCIWRD has adopted a national average value of 15% of the live storage capacity of major projects and 25% of the live storage capacity of minor projects as evaporation losses in the country. The estimated evaporation losses from reservoirs are 42 km3, 50 km3 and 76 km3 by the years 2010, 2025 and 2050 respectively. Demand and Available Water Resources The summary of NCIWRD8 (1999) study relating to national level assessment of demand and available water

186 Engineering Hydrology Table 5.14 Water Requirement for Different Uses (Unit: Cubic Kilometer) [Source: Ref. 8] Sl Uses No. Surface Water 1. Irrigation 2. Domestic 3. Industries 4. Power Inland 5. Navigation Environment 6. (Ecology) Evaporation 7. Losses Total Ground Water 1. Irrigation 2. Domestic 3. Indusrtries 4. Power Total Grand Total

Year 2010 Low High %

Year 2025 Low High %

Year 2050 Low High %

330 23 26 14

339 24 26 15

48 3 4 2

325 30 47 25

366 36 47 26

43 5 6 3

375 48 57 50

463 65 57 56

39 6 5 5

7

7

1

10

10

1

15

15

1

5

5

1

10

10

1

20

20

2

42 447

42 458

6 65

50 497

50 545

6 65

76 641

76 752

6 64

213 19 11 4 247 694

218 19 11 4 252 710

31 2 1 1 35 100

236 25 20 6 287 784

245 26 20 7 298 843

29 3 2 1 35 100

253 344 42 46 24 24 13 14 332 428 973 1180

29 4 2 1 36 100

resources is given in Table 5.15. The utilizable return flow is an important component to be considered in the demand–supply analysis of utilizable water resources. Estimated utilizable return flows of the country in surface and groundwater mode for different time horizons are shown in Table 5.15. It may be noted that the return flow contributes to an extent of nearly 20–25% in reducing the demand. Table 5.15 Utilizable Water, Requirements and Return Flow (Quantity in Cubic Kilometre) [Source: Ref. 8] Sl. Particulars No. 1

Utilizable Water Surface Water Ground water Augmentation from canal Irrigation Total

Year 2010 Year 2025 Year 2050 Low High Low High Low High Demand Demand Demand Demand Demand Demand 690 396

690 396

690 396

690 396

690 396

690 396

90

90

90

90

90

90

996

996

996

996

996

996

Total Water (Contd.)

Runoff

(Contd.) 2 Requirement Surface Water Ground Water 3

4

187

447 247

458 252

497 287

545 298

641 332

752 428

Total

694

710

784

843

973

1180

Return Flow Surface Water Ground Water

52 144

52 148

70 127

74 141

91 122

104 155

Total

196

200

197

215

213

259

Residual Utilizable water Surface Water Ground Water

295 203

284 202

263 146

219 149

140 96

42 33

Total

498

486

409

463

236

75

While the table is self-explanatory, the following significant aspects may be noted: (a) The available water resources of the country are adequate to meet the low demand scenario up to year 2050. However, at high demand scenario it barely meets the demand. (b) Need for utmost efficiency in management of every aspect of water use, conservation of water resources and reducing the water demand to low demand scenario are highlighted.

REFERENCES 1. Central Water Commission, Water Resources of India, CWC Pub. No. 30/88, CWC, New Delhi, India, 1988. 2. Chow, V.T. (Ed.), Handbook of Applied Hydrology, McGraw-Hill, New York, USA, 1964. 3. Chow, V.T., Maidment, D.R. and Mays, L.W., Applied Hydrology, McGraw-Hill, Singapore, 1988. 4. Jal Vigyan Sameeksha (Hydrology Review), Pub. of High Level Tech. Com. on Hydrology, Nat. Inst. of Hydrology, Roorkee, India, Vol. I, No. 1, June 1986. 5. Linsley, R.K. et al, Applied Hydrology, Tata McGraw-Hill, New Delhi, India, 1979. 6. Linsley, R.K. et al, Hydrology for Engineers, SI Metric edition, McGraw-Hill Book Co., Singapore 1988. 7. Ministry of Agriculture, Govt. of India, Handbook of Hydrology, New Delhi, 1972. 8. Min. of Water Resources, GOI, Report of The National Commission for Integrated Water Resources Development, Vol. l, New Delhi, Sept. 1999. 9. Rao, K.L., India’s Water Wealth, Orient Longmans, New Delhi, India, 1975. 10. Ponce, V.M. and Hawkins, R.H., “Runoff Curve Number: Has it reached its maturity?, J. of Hydrologic Engg., ASCE, Vol. 1, No. 1, 1996. 11. Wagner, T.P., and R.K. Linsley, “Application of Stanford Watershed Model to an Indian Catchment”, Irrigation and Power, J. of CBIP (India), Vol. 32, No. 4, Oct. 1975, pp. 465–475.

REVISION QUESTIONS 5.1 List the factors affecting the seasonal and annual runoff (Yield) of a catchment. Describe briefly the interactions of factors listed by you.

188 Engineering Hydrology 5.2 5.3 5.4 5.5 5.6 5.7 5.8 5.9 5.10 5.11 5.12 5.13 5.14 5.15 5.16

With the help of typical hydrographs describe the salient features of (i) Perennial, (ii) intermittent, and (iii) ephemeral steams. Explain briefly: (a) Water year (b) Natural (Virgin) flow What is meant by 75% dependable yield of a catchment? Indicate a procedure to estimate the same by using annual runoff volume time series. Describe briefly the SCS-CN method of estimation yield of a catchment through use of daily rainfall record. Indicate a procedure to estimate the annual yield of a catchment by using Strange’s tables. Explain clearly the procedure for calculating 75% dependable yield of a basin at a flow gauging station. List the essential data series required for this analysis. Distinguish between yield and surface water resources potential of a basin having substantial water resources development for meeting irrigation, domestic and industrial needs within the basin. What is watershed simulation? Explain briefly the various stages in the simulation study. What is a flow-duration curve? What information can be gathered from a study of the flow duration curve of a stream at a site? Sketch a typical flow mass curve and explain how it could be used for the determination of (a) the minimum storage needed to meet a constant demand (b) the maximum constant maintainable demand from a given storage. Describe the use of flow mass curve to estimate the storage requirement of a reservoir to meet a specific demand pattern. What are the limitations of flow mass curve? What is a residual mass curve? Explain the sequent peak algorithm for the calculation of minimum storage required to meet a demand. What is a hydrological drought? What are its components and their possible effects? List the measures that can be adopted to lessen the effects of drought in a region. Describe briefly the surface water resources of India.

PROBLEMS 5.1 Long-term observations at a streamflow-measuring station at the outlet of a catchment in a mountainous area gives a mean annual discharge of 65 m3/s. An isohyetal map for the annual rainfall over the catchment gives the following areas closed by isohyets and the divide of the catchment: Isohyet (cm) 140–135 135–130 130–125 125–120 Calculate

Area (km2)

Isohyet (cm)

Area (km2)

50 300 450 700

120–115 115–110 110–105

600 400 200

(a) the mean annual depth of rainfall over the catchment, (b) the runoff coefficient. 5.2 A small stream with a catchment area of 70 km2 was gauged at a location some distance downstream of a reservoir. The data of the mean monthly gauged flow, rainfall and upstream diversion are given. The regenerated flow reaching the stream upstream of the gauging station can be assumed to be constant at a value of 0.20 Mm3/month. Obtain the rainfall runoff relation for this stream. What virgin flow can be expected for a monthly rainfall value or 15.5 cm?

Runoff Month 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12.

Monthly rainfall (cm)

Gauged monthly flow (Mm3)

5.2 8.6 7.1 9.2 11.0 1.2 10.5 11.5 14.0 3.7 1.6 3.0

1.09 2.27 1.95 2.80 3.25 0.28 2.90 2.98 3.80 0.84 0.28 0.40

189

Upstream utilization (Mm3) 0.60 0.70 0.70 0.70 0.70 0.30 0.70 0.70 0.70 0.30 0.30 0.30

5.3 The following table shows the observed annual rainfall and the corresponding annual runoff for a small catchment. Develop the rainfall–runoff correlation equation for this catchment and find the correlation coefficient. What annual runoff can be expected from this catchment for an annual rainfall of 100 cm? Year Annual Rainfall (cm) Annual Runoff (cm) Year Annual Rainfall (cm) Annual Runoff (cm)

1964

1965

1966

1967

1968

1969

90.5 30.1 1970 147.6 64.7

111.0 50.2 1971 50.9 6.5

38.7 5.3 1972 120.2 46.1

129.5 61.5 1973 90.3 36.2

145.5 74.8 1974 65.2 24.6

99.8 39.9 1975 75.9 20.0

5.4 Flow measurement of river Netravati at Bantwal (catchment area = 3184 km2) yielded the following annual flow volumes: Year 1970–71 1971–72 1972–73 1973–74 1974–75 1975–76 1976–77 1977–78 1978–79 1979–80

Observed annual flow (Mm3) 15925 14813 11726 11818 12617 15704 8334 12864 16195 10392

Year

Observed annual flow (Mm3)

1980–81 1981–82 1982–83 1983–84 1984–85 1985–86 1986–87

16585 14649 10662 11555 10821 9466 9732

The withdrawal upstream of the gauging station [for meeting irrigation, drinking water and industrial needs are 91 Mm3 in 1970–71 and is found to increase linearly at a rate of 2 Mm3/year. The annual evaporation loses from water bodies on the river can be assumed to be 4 Mm3. Estimate the 75% dependable yield at Bantwal. If the catchment area at the mouth of the river is 3222 km2, estimate the average yield for the whole basin. 5.5 The mean monthly rainfall and temperature of a catchment near Bangalore are given below. Estimate the annual runoff volume and the corresponding runoff coefficient by using Khosla’s runoff formula.

190 Engineering Hydrology Month

Jan Feb Mar Apr May Jun July Aug Sep Oct Nov

Temp (°C) 24 Rainfall (mm) 7 5.6

5.7

5.8

27

32

33

31

9

11

45

107

24

71 111

24

23

21

20

21

137 164 153

61

13

An irrigation tank has a catchment of 900 ha. Estimate, by using Strange’s method, the monthly and total runoff volumes into the tank due to following monthly rainfall values. Month

July

Aug

Sept

Oct

Monthly Rainfall (mm)

210

180

69

215

For a 500 ha watershed in South India with predominantly non-black cotton soil, the CNII has been estimated as 68. (a) If the total rainfall in the past five days is 25 cm and the season is dormant season, estimate the runoff volume due to 80 mm of rainfall in a day? (b) What would be the runoff volume if the rainfall in the past five days were 35 mm? Estimate the values of CNI, CNII and CNIII for a catchment with the following land use: Land use Cultivated land (Paddy) Scrub forest Waste land

5.9

26

Dec

Soil group C (%)

Soil group D (%)

Total % area

30 6 9

45 4 6

75 10 15

A 400 ha watershed has predominantly black cotton soil and its CNII value is estimated as 73. Estimate the runoff volume due to two consecutive days of rainfall as follows: Day Rainfall (mm)

Day 1 65

Day 2 80

The AMC can be assumed to be Type III. 5.10 Compute the runoff volume due to a rainfall of 15 cm in a day on a 550 ha watershed. The hydrological soil groups are 50% of group C and 50% of group D, randomly distributed in the watershed. The land use is 55% cultivated with good quality bunding and 45% waste land. Assume antecedent moisture condition of Type-III and use standard SCS-CN equations. 5.11 A watershed having an area 680 ha has a CNIII value of 77. Estimate the runoff volume due to 3 days of rainfall as below: Day Rainfall (mm)

Day 1 30

Day 2 50

Day 3 13

Assume the AMC at Day 1 to be of Type III. Use standard SCS-CN equations. 5.12 A watershed has the following land use: (a) 400 ha of row crop with poor hydrologic condition and (b) 100 ha of good pasture land The soil is of hydrologic soil group B. Estimate the runoff volume for the watershed under antecedent moisture category III when 2 days of consecutive rainfall of 100 mm and 90 mm occur. Use standard SCS-CN equations. 5.13 (a) Compute the runoff from a 2000 ha watershed due to 15 cm rainfall in a day. The watershed has 35% group B soil, 40% group C soil and 25% group D soil. The land

Runoff

191

use is 80% residential that is 65% impervious and 20% paved roads. Assume AMC II conditions. (b) If the land were pasture land in poor condition prior to the development, what would have been the runoff volume under the same rainfall? What is the percentage increase in runoff volume due to urbanization? [Note: Use standard SCS-CN equations.] 5.14 Discharges in a river are considered in 10 class intervals. Three consecutive years of data of the discharge in the river are given below. Draw the flow-duration curve for the river and determine the 75% dependable flow. Discharge range (m3/s) No. of occurrences

350 249 349 60

30

6

5.15 The average monthly inflow into a reservoir in a dry year is given below: Month Mean monthly flow (m3/s)

Jun Jul Aug Sep Oct Nov Dec Jan Feb Mar Apr

20

60

200 300 200 150 100

80

60

40

30

May

25

If a uniform discharge at 90 m3/s is desired from this reservoir what minimum storage capacity is required? (Hints: Assume the next year to have similar flows as the present year.) 5.16 For the data given in Prob. 5.15, plot the flow mass curve and find: (a) The minimum storage required to sustain a uniform demand of 70 m3/s; (b) If the reservoir capacity is 7500 cumec-day, estimate the maximum uniform rate of withdrawal possible from this reservoir. 5.17 The following table gives the monthly inflow and contemplated demand from a proposed reservoir. Estimate the minimum storage that is necessary to meet the demand Month Monthly inflow (Mm3) Monthly demand (Mm3)

Jan Feb Mar Apr May Jun July Aug Sept Oct Nov

Dec

50

40

30

25

20

70

75

80

85

130 120

30

200 225 150

90

70

60

25

45

50

60

25

40

5.18 For the reservoir in Prob. 5.17 the mean monthly evaporation and rainfall are given below. Month Evaporation (cm) Rainfall (cm)

Jan Feb Mar Apr May Jun July Aug Sept Oct Nov Dee

6

8

13

17

22

22

14

11

13

12

7

5

1

19

43

39

22

6

2

1

192 Engineering Hydrology If the average reservoir area can be assumed to be 30 km2, estimate the change in the storage requirement necessitated by this additional data. Assume the runoff coefficient of the area flooded by the reservoir as equal to 0.4. 5.19 Following is the stream flow record of a stream and covers a critical 2 year period. What is the minimum size of the reservoir required on this stream to provide a constant downstream flow of 0.07 cumecs? Use Sequent Peak Algorithm. Month (1st Year)

Monthly Discharge (ha.m)

Jan Feb March April May June July Aug Sept Oct Nov Dec

Month (2nd Year)

57.4 65.5 28.6 32.8 36.9 24.6 10.2 2.1 2.1 2.1 4.1 8.2

Monthly Discharge (ha.m)

Jan Feb March April May June July Aug Sept Oct Nov Dec

10.2 30.8 43.1 53.1 38.9 28.9 16.4 12.3 12.3 4.1 8.2 2.1

5.20 Solve Problem 5.18 using Sequent Peak Algorithm method. 5.21 An unregulated stream provides the following volumes through each successive 4-day period over a 40-day duration at a possible reservoir site. What would be the reservoir capacity needed to ensure maintaining the average flow over these 40 days, if the reservoir is full to start with? What is the average flow? What would be the approximate quantity of water wasted in spillage in this case? Day

4

8

12

16

20

24

28

32

Runoff volume (Mm3)

36

40

9.6

5.4

2.3

3.5

2.3

2.2

1.4

6.4 12.4 10.9

5.22 A reservoir is located in a region where the normal annual precipitation is 160 cm and the normal annual US class A pan evaporation is 200 cm. The average area of reservoir water surface is 75 km2. If under conditions of 35% of the rainfall on the land occupied by the reservoir runoff into the stream, estimate the net annual increase or decrease in the stream flow as result of the reservoir. Assume evaporation pan coefficient = 0.70.

OBJECTIVE QUESTIONS 5.1 A mean annual runoff of 1 m3/s from a catchment of area 31.54 km2 represents an effective rainfall of (a) 100 cm (b) 1.0 cm (e) 100 mm (d) 3.17 cm 5.2 Direct runoff is made up of (a) Surface runoff, prompt interflow and channel precipitation (b) Surface runoff, infiltration and evapotranspiration (c) Overland flow and infiltration (d) Rainfall and evaporation

Runoff 5.3

193

A hydrograph is a plot of (a) rainfall intensity against time (b) stream discharge against time (c) cumulative rainfall against time (d) cumulative runoff against time 5.4 The term base flow denotes (a) delayed groundwater flow reaching a stream (b) delayed groundwater and snowmelt reaching a stream (c) delayed groundwater and interflow (d) the annual minimum flow in a stream 5.5 Virgin flow is (a) the flow in the river downstream of a gauging station (b) the flow in the river upstream of a gauging station (c) the flow unaffected by works of man (d) the flow that would exist in the stream if there were no abstractions to the precipitation 5.6 The water year in India starts from the first day of (a) January (b) April (c) June (d) September 5.7 An ephemeral stream (a) is one which always carries some flow (b) does not have any base flow contribution (c) is one which has limited contribution of groundwater in wet season (d) is one which carries only snow-melt water. 5.8 An intermittent stream (a) has water table above the stream bed throughout the year (b) has only flash flows in response to storms (c) has flows in the stream during wet season due to contribution of groundwater. (d) does not have any contribution of ground water at any time 5.9 Khosla’s formula for monthly runoff Rm due to a monthly rainfall Pm is Rm = Pm – Lm where Lm is (a) a constant (b) monthly loss and depends on the mean monthly catchment temperature (c) a monthly loss coefficient depending on the antecedent precipitation index (d) a monthly loss depending on the infiltration characteristics of the catchment 5.10 The flow-duration curve is a plot of (a) accumulated flow against time (b) discharge against time in chronological order (c) the base flow against the percentage of times the flow is exceeded (d) the stream discharge against the percentage of times the flow is equalled or exceeded. 5.11 In a flow–mass curve study the demand line drawn from a ridge in the curve did not interest the mass curve again. This represents that (a) the reservoir was not full at the beginning (b) the storage was not adequate (c) the demand cannot be met by the inflow as the reservoir will not refill (d) the reservoir is wasting water by spill. 5.12 If in a flow–mass curve, a demand line drawn tangent to the lowest point in a valley of the curve does not intersect the mass curve at an earlier time period, it represents that (a) the storage is inadequate (b) the reservoir will not be full at the start of the dry period (c) the reservoir is full at the beginning of the dry period (d) the reservoir is wasting later by spill.

194 Engineering Hydrology 5.13 The flow-mass curve is an integral curve of (a) the hydrograph (b) the hyetograph (c) the flow duration curve (d) the S-curve. 5.14 The total rainfall in a catchment of area 1200 km2 during a 6-h storm is 16 cm while the surface runoff due to the storm is 1.2 ´ 108 m3. The f index is (a) 0.1 cm/h (b) 1.0 cm/h (c) 0.2 cm/h (d) cannot be estimated with the given data. 5.15 In India, a meteorological subdivision is considered to be affected by moderate drought if it receives a total seasonal rainfall which is (a) less than 25% of normal value (b) between 25% and 49% of normal value (c) between 50% and 74% of normal value (d) between 75% and 99% of normal value 5.16 An area is classified as a drought prone area if the probability P of occurrence of a drought is (a) 0.4 < P £ 1.0 (b) 0.2 £ P £ 0.40 (c) 0.1 £ P < 0.20 (d) 0.0 < P < 0.20 5.17 In the standard SCS-CN method of modelling runoff due to daily rainfall, the maximum daily rainfall that would not produce runoff in a watershed with CN = 50 is about (a) 65 mm (b) 35 mm (c) 50 mm (d) 25 mm 5.18 In the standard SCS-CN method, if CN = 73 the runoff volume for a one day rainfall of 100 mm is about (a) 38 mm (b) 2 mm (c) 56 mm (d) 81 mm

Chapter

6

HYDROGRAPHS

6.1 INTRODUCTION While long-term runoff concerned with the estimation of yield was discussed in the previous chapter, the present chapter examines in detail the short-term runoff phenomenon. The storm hydrograph is the focal point of the present chapter. Consider a concentrated storm producing a fairly uniform rainfall of duration, D over a catchment. After the initial losses and infiltration losses are met, the rainfall excess reaches the stream through overland and channel flows. In the process of translation a certain amount of storage is built up in the overland and channel-flow phases. This storage gradually depletes after the cessation of the rainfall. Thus there is a time lag between the occurrence of rainfall in the basin and the time when that water passes the gauging station at the basin outlet. The runoff measured at the stream-gauging station will give a typical hydrograph as shown in Fig. 6.1. The duration of the rainfall is also marked in this figure to indicate the time lag in the rainfall and runoff. The hydrograph of this kind which results due to an isolated storm is typically singlepeaked skew distribution of discharge and is known variously as storm hydrograph, flood hydrograph or simply hydrograph. It has three characteristic regions: (i) the rising limb AB, joining point A, the starting point of the rising curve and point B, the point of inflection, (ii) the crest segment BC between the two points of inflection with a peak P in between, (iii) the falling limb or depletion curve CD starting from the second point of inflection C.

Fig. 6.1 Elements of a Flood Hydrograph

196 Engineering Hydrology The hydrograph is the response of a given catchment to a rainfall input. It consists of flow in all the three phases of runoff, viz. surface runoff, interflow and base flow, and embodies in itself the integrated effects of a wide variety of catchment and rainfall parameters having complex interactions. Thus two different storms in a given catchment produce hydrographs differing from each other. Similarly, identical storms in two catchments produce hydrographs that are different. The interactions of various storms and catchments are in general extremely complex. If one examines the record of a large number of flood hydrographs of a stream, it will be found that many of them will have kinks, multiple peaks, etc. resulting in shapes much different from the simple single-peaked hydrograph of Fig. 6.1. These complex hydrographs are the result of storm and catchment peculiarities and their complex interactions. While it is theoretically possible to resolve a complex hydrograph into a set of simple hydrographs for purposes of hydrograph analysis, the requisite data of acceptable quality are seldom available. Hence, simple hydrographs resulting from isolated storms are preferred for hydrograph studies.

6.2 FACTORS AFFECTING FLOOD HYDROGRAPH The factors that affect the shape of the hydrograph can be broadly grouped into climatic factors and physiographic factors. Each of these two groups contains a host of factors and the important ones are listed in Table 6.1. Generally, the climatic factors control the rising limb and the recession limb is independent of storm characteristics, being determined by catchment characteristics only. Many of the factors listed in Table 6.1 are interdependent. Further, their effects are very varied and complicated. As such only important effects are listed below in qualitative terms only. Table 6.1 Factors Affecting Flood Hydrograph Physiographic factors 1. Basin characterstics: (a) Shape (b) size (c) slope (d) nature of the valley (e) elevation (f) drainage density

Climatic factors 1. Storm characterstics: precipitation, intensity, duration, magnitude and movement of storm. 2. Initial loss 3. Evapotranspiration

2. Infiltration characteristics: (a) land use and cover (b) soil type and geological conditions (c) lakes, swamps and other storage 3. Channel characteristics: cross-section, roughness and storage capacity

Shape of the Basin The shape of the basin influences the time taken for water from the remote parts of the catchment to arrive at the outlet. Thus the occurrence of the peak and hence the shape

Hydrographs

197

of the hydrograph are affected by the basin shape. Fan-shaped, i.e. nearly semi-circular shaped catchments give high peak and narrow hydrographs while elongated catchments give broad and low-peaked hydrographs. Figure 6.2 shows schematically the hydrographs from three catchments having identical infiltration characteristics due to identical rainfall over the catchment. In catchment A the hydrograph is skewed to the left, i.e. the peak occurs relatively quickly. In catchment B, the hydrograph is skewed to the right, the peak occurring with a relatively longer lag. Catchment C indicates the complex hydrograph produced by a composite shape.

Fig. 6.2 Effect of Catchment Shape on the Hydrograph

Size Small basins behave different from the large ones in terms of the relative importance of various phases of the runoff phenomenon. In small catchments the overland flow phase is predominant over the channel flow. Hence the land use and intensity of rainfall have important role on the peak flood. On large basins these effects are suppressed as the channel flow phase is more predominant. The peak discharge is found to vary as An where A is the catchment area and n is an exponent whose value is less than unity, being about 0.5. The time base of the hydro-graphs from larger basins will be larger than those of corresponding hydrographs from smaller basins. The duration of the surface runoff from the time of occurrence of the peak is proportional to Am, where m is an exponent less than unity and is of the order of magnitude of 0.2.

Slope The slope of the main stream controls the velocity of flow in the channel. As the recession limb of the hydrograph represents the depletion of storage, the stream channel slope will have a pronounced effect on this part of the hydrograph. Large stream slopes give rise to quicker depletion of storage and hence result in steeper recession limbs of hydrographs. This would obviously result in a smaller time base. The basin slope is important in small catchments where the overland flow is relatively more important. In such cases the steeper slope of the catchment results in larger peak discharges.

Drainage Density The drainage density is defined as the ratio of the total channel length to the total drainage area. A large drainage density creates situation conducive for quick disposal of runoff down the channels. This fast response is reflected in a pronounced peaked discharge. In basins with smaller drainage densities, the overland flow is predominant and the resulting hydrograph is squat with a slowly rising limb (Fig. 6.3).

198 Engineering Hydrology

Land Use Vegetation and forests increase the infiltration and storage capacities of the soils. Further, they cause considerable retardance to the overland flow. Thus the vegetal cover reduces the peak flow. This effect is usually very pronounced in small catchments of area less than 150 km2. Further, the effect of the vegetal cover is prominent in small storms. In general, for two catchments of equal area, Fig. 6.3 Role of Drainage Density other factors being identical, the peak dison the Hydrograph charge is higher for a catchment that has a lower density of forest cover. Of the various factors that control the peak discharge, probably the only factor that can be manipulated is land use and thus it represents the only practical means of exercising long-term natural control over the flood hydrograph of a catchment.

Climatic Factors Among climatic factors the intensity, duration and direction of storm movement are the three important ones affecting the shape of a flood hydrograph. For a given duration, the peak and volume of the surface runoff are essentially proportional to the intensity of rainfall. This aspect is made use of in the unit hydrograph theory of estimating peak-flow hydrographs, as discussed in subsequent sections of this chapter. In very small catchments, the shape of the hydrograph can also be affected by the intensity. The duration of storm of given intensity also has a direct proportional effect on the volume of runoff. The effect of duration is reflected in the rising limb and peak flow. Ideally, if a rainfall of given intensity i lasts sufficiently long enough, a state of equilibrium discharge proportional to iA is reached. If the storm moves from upstream of the catchment to the downstream end, there will be a quicker concentration of flow at the basin outlet. This results in a peaked hydrograph. Conversely, if the storm movement is up the catchment, the resulting hydrograph will have a lower peak and longer time base. This effect is further accentuated by the shape of the catchment, with long and narrow catchments having hydrographs most sensitive to the storm-movement direction.

6.3 COMPONENTS OF A HYDROGRAPH As indicated earlier, the essential components of a hydrograph are: (i) the rising limb, (ii) the crest segment, and (iii) the recession limb (Fig. 6.1). A few salient features of these components are described below.

Rising Limb The rising limb of a hydrograph, also known as concentration curve represents the increase in discharge due to the gradual building up of storage in channels and over the catchment surface. The initial losses and high infiltration losses during the early period of a storm cause the discharge to rise rather slowly in the initial periods. As the

Hydrographs

199

storm continues, more and more flow from distant parts reach the basin outlet. Simultaneously the infiltration losses also decrease with time. Thus under a uniform storm over the catchment, the runoff increases rapidly with time. As indicated earlier, the basin and storm characteristics control the shape of the rising limb of a hydrograph.

Crest Segment The crest segment is one of the most important parts of a hydrograph as it contains the peak flow. The peak flow occurs when the runoff from various parts of the catchment simultaneously contribute amounts to achieve the maximum amount of flow at the basin outlet. Generally for large catchments, the peak flow occurs after the cessation of rainfall, the time interval from the centre of mass of rainfall to the peak being essentially controlled by basin and storm characteristics. Multiple-peaked complex hydrographs in a basin can occur when two or more storms occur in succession. Estimation of the peak flow and its occurrence, being important in flood-flow studies are dealt with in detail elsewhere in this book.

Recession Limb The recession limb, which extends from the point of inflection at the end of the crest segment (point C in Fig. 6.1) to the commencement of the natural groundwater flow (point D in Fig. 6.1) represents the withdrawal of water from the storage built up in the basin during the earlier phases of the hydrograph. The starting point of the recession limb, i.e. the point of inflection represents the condition of maximum storage. Since the depletion of storage takes place after the cessation of rainfall, the shape of this part of the hydrograph is independent of storm characteristics and depends entirely on the basin characteristics. The storage of water in the basin exists as (i) surface storage, which includes both surface detention and channel storage, (ii) interflow storage, and (iii) groundwater storage, i.e. base-flow storage. Barnes (1940) showed that the recession of a storage can be expressed as Qt = Q0K rt (6.1) in which Qt is the discharge at a time t and Q0 is the discharge at t = 0; Kr is a recession constant of value less than unity. Equation (6.1) can also be expressed in an alternative form of the exponential decay as Qt = Q0e–at (6.1a) where a = –ln Kr. The recession constant Kr can be considered to be made up of three components to account for the three types of storages as Kr = Krs × Kri × Krb where Krs = recession constant for surface storage, Kri = recession constant for interflow and Krb = recession constant for base flow. Typically the values of these recession constants, when time t is in days, are Krs = 0.05 to 0.20 Kri = 0.50 to 0.85 Krb = 0.85 to 0.99 When the interflow is not significant, Kri can be assumed to be unity. If suffixes 1 and 2 denote the conditions at two time instances t1 and t2,

200 Engineering Hydrology

Q1

from Eq. (6.1)

Q2 Q1

( t1 - t2 )

= Kr

(6.2)

= e - a ( t1 - t2 ) (6.2a) Q2 Equation 6.1 (and also 6.1a) plots as a straight line when plotted on a semi-log paper with discharge on the log–scale. The slope of this line represents the recession constant. Using this property and using Eq. 6.2 (or 6.2a) the value of Kr for a basin can be estimated by using observed recession data of a flood hydrograph. Example 6.1 explains the procedure in detail. The storage St remaining at any time t is obtained as ¥ ¥ Qt St = ò Qt dt = ò Q0 e - at dt = (6.3) a t t or from Eq. (6.1a)

EXAMPLE 6.1 The recession limb of a flood hydrograph is given below. The time is indicated from the arrival of peak. Assuming the interflow component to be negligible, estimate the base flow and surface flow recession coefficients. Also, estimate the storage at the end of day-3. Time from peak (day)

Discharge (m3/s)

Time from Peak (day)

Discharge (m3/s)

0.0 0.5 1.0 1.5 2.0 2.5 3.0

90 66 34 20 13 9.0 6.7

3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0

5.0 3.8 3.0 2.6 2.2 1.8 1.6 1.5

SOLUTION: The data are plotted on a semi-log paper with discharge on the log-scale. The data points from t = 4.5 days to 7.0 days are seen to lie on straight line (line AB in Fig. 6.4). This indicates that the surface flow terminates at t = 4.5 days. The best fitting exponential curve for this straight-line portion (obtained by use of MS Excel) is Qt = 11.033e–0.2927t with R2 = 0.9805. The base flow recession coefficient Krb is obtained as ln Krb = –0.2927 and as such Krb = 0.746. [Alternatively, by using the graph, the value of Krb could be obtained by selecting two points 1 and 2 on the straight line AB and using Eq. (6.2)]. The base flow recession curve is extended till t » 1 day as shown by line ABM Fig. 6.4. The Surface runoff depletion is obtained by subtracting the base flow from the given recession limb of the flood hydrograph. The computations are shown in the Table given on the next page. The surface flow values (Col. 4 of Table above) are plotted against time as shown in Fig. 6.4. It is seen that these points lie on a straight line, XY. The best fitting exponential curve for this straight-line portion XY (obtained by use of MS Excel) is Qt = 106.84e–1.3603t with R2 = 0.9951

Hydrographs

201

Fig. 6.4 Storage Recession Curve—Example 6.1 Time from peak (days) 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0

Recession Limb of given flood hydrograph (m3/s)

Base flow (Obtained by using Krb = 0.746)

90.0 66.0 34.0 20.0 13.0 9.0 6.7 5.0 3.8 3.0 2.6 2.2 1.8 1.6 1.5

10.455 7.945 6.581 5.613 4.862 4.249 3.730 3.281 2.884 2.530 2.209 1.917 1.647 1.398

Surface runoff (m3/s)

55.545 26.055 13.419 7.387 4.138 2.451 1.270 0.519

The Surface flow recession coefficient Krs is obtained as ln Krs = –1.3603 and as such Krs = 0.257. [Alternatively, by using the graph, the value of Krs could be obtained by selecting two points 1 and 2 on the straight line XY and using Eq. (6.2)]. The storage available at the end of day-3 is the sum of the storages in surface flow and groundwater recession modes and is given by

Qb 3 ö æ Qs 3 St3 = ç + ÷ – ln K rb ø è - ln K rs

202 Engineering Hydrology For the surface flow recession using the best fit equation: Qs3 = 106.84e–1.3603 ´ 3 = 1.8048; – ln Krs = 1.3603 Qs 3 1.8048 = = 1.3267 cumec-days 1.3603 - ln K rs Similarly for the base flow recession: Qb3 = 11.033e–0.2927 ´ 3 = 4.585; –ln Krb = 0.2927 Qb 3 4.585 = = 15.665 cumec-days 0.2927 - ln K rb Hence, total storage at the end of 3 days = St3 = 1.3267 + 15.665 = 16.9917 cumec. days = 1.468 Mm3

6.4 BASE FLOW SEPARATION In many hydrograph analyses a relationship between the surface-flow hydrograph and the effective rainfall (i.e. rainfall minus losses) is sought to be established. The surface-flow hydrograph is obtained from the total storm hydrograph by separating the quick-response flow from the slow response runoff. It is usual to consider the interflow as a part of the surface flow in view of its quick response. Thus only the base flow is to be deducted from the total storm hydrograph to obtain the surface flow hydrograph. There are three methods of base-flow separation that are in common use.

Methods of Base-flow Separation Method I—Straight-Line Method In this method the separation of the base flow is achieved by joining with a straight line the beginning of the surface runoff to a point on the recession limb representing the end of the direct runoff. In Fig. 6.5 point A represents the beginning of the direct runoff and it is usually easy to identify in view of the sharp change in the runoff rate at that point. Point B, marking the end of the direct runoff is rather difficult to locate exactly. An empirical equation for the time inter- Fig. 6.5 Base Flow Seperation Methods val N (days) from the peak to the point B is N = 0.83A0.2 (6.4) 2 where A = drainage area in km and N is in days. Points A and B are joined by a straight line to demarcate to the base flow and surface runoff. It should be realised that the value of N obtained as above is only approximate and the position of B should be decided by considering a number of hydrographs for the catchment. This method of base-flow separation is the simplest of all the three methods. Method 2 In this method the base flow curve existing prior to the commencement of the surface runoff is extended till it intersects the ordinate drawn at the peak (point C in Fig. 6.5). This point is joined to point B by a straight line. Segment AC and CB demarcate the base flow and surface runoff. This is probably the most widely used base-flow separation procedure.

Hydrographs

203

Method 3 In this method the base flow recession curve after the depletion of the flood water is extended backwards till it intersects the ordinate at the point of inflection (line EF in Fig. 6.5). Points A and F are joined by an arbitrary smooth curve. This method of base-flow separation is realistic in situations where the groundwater contributions are significant and reach the stream quickly. It is seen that all the three methods of base-flow separation are rather arbitrary. The selection of anyone of them depends upon the local practice and successful predictions achieved in the past. The surface runoff hydrograph obtained after the base-flow separation is also known as direct runoff hydrograph (DRH).

6.5 EFFECTIVE RAINFALL (ER) Effective rainfall (also known as Excess rainfall) (ER) is that part of the rainfall that becomes direct runoff at the outlet of the watershed. It is thus the total rainfall in a given duration from which abstractions such as infiltration and initial losses are subtracted. As such, ER could be defined as that rainfall that is neither retained on the land surface nor infiltrated into the soil. For purposes of correlating DRH with the rainfall which produced the flow, the hyetograph of the rainfall is also pruned by deducting the losses. Figure 6.6 shows the hyetograph of a storm. The initial loss and infiltration losses are subtracted from it. The resulting hyetograph is known as effective rainfall hyetograph (ERH). It is also known as excess rainfall hyetograph. Both DRH and ERH represent the same total Fig. 6.6 Effective Rainfall quantity but in different units. Since ERH is usuHyetograph (ERH) ally in cm/h plotted against time, the area of ERH multiplied by the catchment area gives the total volume of direct runoff which is the same as the area of DRH. The initial loss and infiltration losses are estimated based on the available data of the catchment. EXAMPLE 6.2 Rainfall of magnitude 3.8 cm and 2.8 cm occurring on two consecutive 4-h durations on a catchment of area 27 km2 produced the following hydrograph of flow at the outlet of the catchment. Estimate the rainfall excess and B index. Time from start of rainfall (h) –6 Observed flow (m3/s) 6

6

12

18

24

30

36

42

48

5

13

26

21

16

12

9

7

5

54

60

66

5 4.5 4.5

SOLUTION: The hydrograph is plotted to scale (Fig. 6.7). It is seen that the storm hydrograph has a base-flow component. For using the simple straight-line method of baseflow separation, by eg. (6.4)

N = 0.83 ´ (27)0.2 = 1.6 days = 38.5 h

However, by inspection, DRH starts at t = 0, has the peak at t = 12 h and ends at t = 48 h (which gives a value of N = 48 – 12 = 36 h). As N = 36 h appears to be more satisfactory

204 Engineering Hydrology

Fig. 6.7 Base Flow Separation—Example 6.2 than N = 38.5 h, in the present case DRH is assumed to exist from t = 0 to 48 h. A straight line base flow separation gives a constant value of 5 m3/s for the base flow. 1 1 1 1 Area of DRH = (6 ´ 60 ´ 60) éê (8) + (8 + 21) + (21 + 16) + (16 + 11) 2 2 2 ë2 1 1 1 1 (11 + 7) + (7 + 4) + (4 + 2) + (2) ùú 2 2 2 2 û = 3600 ´ 6 ´ (8 + 21 + 16 + 11 + 7 + 4 + 2) = 1.4904 ´ 106 m3 = Total direct runoff due to storm runoff volume 1.4904 ´ 106 = = 0.0552 m = catchment area 27 ´ 106 = 5.52 cm = rainfall excess = 3.8 + 2.8 = 6.6 cm =8h 6.6 - 5.52 = = 0.135 cm/h 8

+

Runoff depth Total rainfall Duration B index

EXAMPLE 6.3 A storm over a catchment of area 5.0 km2 had a duration of 14 hours. The mass curve of rainfall of the storm is as follows: Time from start of storm (h) Accumulated rainfall (cm)

2

4

6

8

0.6

2.8

5.2

6.6

10 7.5

12 9.2

14 9.6

If the B index for the catchment is 0.4 cm/h, determine the effective rainfall hyetograph and the volume of direct runoff from the catchment due to the storm.

SOLUTION: First the depth of rainfall in a time interval Dt = 2 hours, in total duration of the storm is calculated, (col. 4 of Table 6.2).

Hydrographs

205

Table 6.2 Calculation for Example 6.3 Time from Time start of interval storm, t (h) Dt (h)

Accumulated Depth of rainfall in rainfall in time t (cm) D t (cm)

j Dt (cm)

ER (cm)

Intensity of ER (cm/h)

1

2

3

4

5

6

7

0 2 4 6 8 10 12 14

— 2 2 2 2 2 2 2

0 0.6 2.8 5.2 6.7 7.5 9.2 9.6

— 0.6 2.2 2.4 1.5 0.8 1.7 0.4

— 0.8 0.8 0.8 0.8 0.8 0.8 0.8

— 0 1.4 1.6 0.7 0 0.9 0

— 0 0.7 0.8 0.35 0 0.45 0

In a given time interval Dt, effective rainfall (ER) is given by ER = (actual depth of rainfall – B D t) or ER = 0, whichever is larger. The calculations are shown in Table 6.2. For plotting the hyetograph, the intensity of effective rainfall is calculated in col. 7. The effective rainfall hyetograph is obtained by plotting ER intensity (col. 7) against time from start of storm (col. 1), and is shown in Fig. 6.8. Total effective rainfall = Direct runoff due to storm = area of ER hyetograph = (0.7 + 0.8 + 0.35 + 0.45) ´ 2 = 4.6 cm 4.6 Volume of Direct runoff = 1000 ´ 5.0 ´ (1000)2 = 23000 m3

Fig. 6.8 ERH of Storm—Example 6.3

6.6 UNIT HYDROGRAPH The problem of predicting the flood hydrograph resulting from a known storm in a catchment has received considerable attention. A large number of methods are proposed to solve this problem and of them probably the most popular and widely used method is the unit-hydrograph method. This method was first suggested by Sherman in 1932 and has undergone many refinements since then. A unit hydrograph is defined as the hydrograph of direct runoff resulting from one unit depth (1 cm) of rainfall excess occurring uniformly over the basin and at a uniform rate for a specified duration (D hours). The term unit here refers to a unit depth of rainfall excess which is usually taken as 1 cm. The duration, being a very important characteristic, is used as a prefix to a specific unit hydrograph. Thus one has a 6-h unit hydrograph, 12-h unit hydrograph, etc. and in general a D-h unit hydrograph applicable to a given catchment. The definition of a unit hydrograph implies the following:

206 Engineering Hydrology The unit hydrograph represents the lumped response of the catchment to a unit rainfall excess of D-h duration to produce a direct-runoff hydrograph. It relates only the direct runoff to the rainfall excess. Hence the volume of water contained in the unit hydrograph must be equal to the rainfall excess. As 1 cm depth of rainfall excess is considered the area of the unit hydrograph is equal to a volume given by 1 cm over the catchment. l The rainfall is considered to have an average intensity of excess rainfall (ER) of 1/D cm/h for the duration D-h of the storm. l The distribution of the storm is considered to be uniform all over the catchment. Figure 6.9 shows a typical 6-h unit hydrograph. Here the duration of the rainfall excess is 6 h. Area under the unit hydrograph = 12.92 ´ 106 m3 l

Fig. 6.9 Typical 6-h Unit Hydrograph Hence

Catchment area of the basin = 1292 km2 Two basic assumptions constitute the foundations for the unit-hydrograph theory. These are: (i) the time invariance and (ii) the linear response.

Time Invariance This first basic assumption is that the direct-runoff response to a given effective rainfall in a catchment is time-invariant. This implies that the DRH for a given ER in a catchment is always the same irrespective of when it occurs.

Linear Response The direct-runoff response to the rainfall excess is assumed to be linear. This is the most important assumption of the unit-hydrograph theory. Linear response means that if an input x1 (t) causes an output y1 (t) and an input x2 (t) causes an output y2 (t), then an input x1 (t) + x2 (t) gives an output yI (t) + y2 (t). Consequently, if x2 (t) = r x1 (t),

Hydrographs

207

then y2 (t) = r y1 (t). Thus, if the rainfall excess in a duration D is r times the unit depth, the resulting DRH will have ordinates bearing ratio r to those of the corresponding D-h unit hydrograph. Since the area of the resulting DRH should increase by the ratio r, the base of the DRH will be the same as that of the unit hydrograph. The assumption of linear response in a unit hydrograph enables the method of superposition to be used to derive DRHs. Accordingly, if two rainfall excess of D-h duration each occur consecutively, their combined effect is obtained by superposing the respective DRHs with due care being taken to account for the proper sequence of events. These aspects resulting from the assumption of linear response are made clearer in the following two illustrative examples. EXAMPLE 6.4 Given below are the ordinates of a 6-h unit hydrograph for a catchment. Calculate the ordinates of the DRH due to a rainfall excess of 3.5 cm occurring in 6 h. Time (h) 0 UH ordinate (m3/s) 0

3

6

9

12

15

18

24

30 36 42 48 54 60 69

25 50 85 125 160 185 160 110 60 36 25 16

8

SOLUTION: The desired ordinates of the DRH are obtained by multiplying the ordinates of the unit hydrograph by a factor of 3.5 as in Table 6.3. The resulting DRH as also the unit hydrograph are shown in Fig. 6.10 (a). Note that the time base of DRH is not changed and remains the same as that of the unit hydrograph. The intervals of coordinates of the unit hydrograph (shown in column 1) are not in any way related to the duration of the rainfall excess and can be any convenient value. Table 6.3 Calculation of DRH Due to 3.5 ER—Example 6.4 Time (h)

Ordinate of 6-h unit hydrograph (m3/s)

Ordinate of 3.5 cm DRH (m3/s)

1

2

3

0 3 6 9 12 15 18 24 30 36 42 48 54 60 69

0 25 50 85 125 160 185 160 110 60 36 25 16 8 0

0 87.5 175.0 297.5 437.5 560.0 647.5 560.0 385.0 210.0 126.0 87.5 56.0 28.0 0

208 Engineering Hydrology

Fig. 6.10(a) 3.5 cm DRH derived from 6-h Unit Hydrograph—Example 6.4 EXAMPLE 6.5 Two storms each of 6-h duration and having rainfall excess values of 3.0 and 2.0 cm respectively occur successively. The 2-cm ER rain follows the 3-cm rain. The 6-h unit hydrograph for the catchment is the same as given in Example 6.4. Calculate the resulting DRH. SOLUTION: First, the DRHs due to 3.0 and 2.0 cm ER are calculated, as in Example 6.3 by multiplying the ordinates of the unit hydrograph by 3 and 2 respectively. Noting that the 2-cm DRH occurs after the 3-cm DRH, the ordinates of the 2-cm DRH are lagged by 6 hrs as shown in column 4 of Table 6.4. Columns 3 and 4 give the proper sequence of the two DRHs. Using the method of superposition, the ordinates of the resulting DRH are obtained by combining the ordinates of the 3- and 2-cm DRHs at any instant. By this process the ordinates of the 5 cm DRH are obtained in column 5. Figure 6.10(b) shows the component 3- and 2-cm DRHs as well as the composite 5-cm DRH obtained by the method of superposition. Table 6.4 Calculation of DRH by method of Superposition—Example 6.5 Time (h)

Ordinate of 6-h UH (m3/s)

Ordinate of 3-cm DRH (col. 2) ´ 3

Ordinate of 2-cm DRH (col. 2 lagged by 6 h) ´ 2

Ordinate of 5-cm DRH (col. 3 + col. 4) (m3/s)

Remarks

1

2

3

4

5

6

0 3 6 9 12 15 18

0 25 50 85 125 160 185

0 75 150 255 375 480 555

0 0 0 50 100 170 250

0 75 150 305 475 650 805 (Contd.)

Hydrographs

(Contd.) (21)

(172.5)

(517.5)

(320)

(837.5)

24 30 36 42 48 54 60 (66)

160 110 60 36 25 16 8 (2.7)

480 330 180 108 75 48 24 (8.1)

370 320 220 120 72 50 32 (16)

850 650 400 228 147 98 56 (24.1)

(10.6)

(10.6)

69

75

Note:

209

Interpolated value

Interpolated value Interpolated value

1. The entries in col. 4 are shifted by 6 h in time relative to col. 2. 2. Due to unequal time interval of ordinates a few entries have to be interpolated to complete the table. These interpolated values are shown in parentheses.

Fig. 6.10(b) Principle of Superposition—Example 6.5

Application of Unit Hydrograph Using the basic principles of the unit hydrograph, one can easily calculate the DRH in a catchment due to a given storm if an appropriate unit hydrograph was available. Let it be assumed that a D-h unit-hydrograph and the storm hyetograph are available. The initial losses and infiltration losses are estimated and deducted from the storm hyetograph to obtain the ERH (Sec. 6.5). The ERH is then divided into M blocks of

210 Engineering Hydrology D-h duration each. The rainfall excess in each D-h duration is then operated upon the unit hydrograph successively to get the various DRH curves. The ordinates of these DRHs are suitably lagged to obtain the proper time sequence and are then collected and added at each time element to obtain the required net DRH due to the storm. Consider Fig. 6.11 in which a sequence of M rainfall excess values R1, R2, …, Ri, … Rm each of duration Dh is shown. The line u [t] is the ordinate of a D-h unit hydrograph at t h from the beFig. 6.11 DRH due to an ERH ginning. The direct runoff due to R1 at time t is Q1 = R1 × u[t] The direct runoff due to R2 at time (t – D) is Q2 = R2 × u [t – D] Similarly, Qi = Ri × u [t – (i – 1) D] and Qm = Rm × u [t – (M – 1) D] Thus at any time t, the total direct runoff is Qt =

M

M

i =1

i =1

å Qi = å Ri × u[t – (i – 1) D]

(6.5)

The arithmetic calculations of Eq. (6.5) are best performed in a tabular manner as indicated in Examples 6.5 and 6.6. After deriving the net DRH, the estimated base flow is then added to obtain the total flood hydrograph. Digital computers are extremely useful in the calculations of flood hydrographs through the use of unit hydrograph. The electronic spread sheet (such as MS Excel) is ideally suited to perform the DRH calculations and to view the final DRH and flood hydrographs. EXAMPLE 6.6 The ordinates of a 6-hour unit hydrograph of a catchment is given below. Time (h) Ordinate of 6-h UH Time (h) Ordinate of 6-h UH

3

6

9

12

15

18

24

30

36

42

48

25

50

85

125

160

185

160

110

60

36

25

54

60

69

16

8

Derive the flood hydrograph in the catchment due to the storm given below: Time from start of storm (h) Accumulated rainfall (cm)

0 0

6 3.5

12 11.0

18 16.5

Hydrographs

211

The storm loss rate (B – index) for the catchment is estimated as 0.25 cm/h. The base flow can be assumed to be 15 m3/s at the beginning and increasing by 2.0 m3/s for every 12 hours till the end of the direct-runoff hydrograph.

SOLUTION: The effective rainfall hyetograph is calculated as in the following table. The direct runoff hydrograph is next calculated by the method of superposition as indicated in Table 6.5. The ordinates of the unit hydrograph are multiplied by the ER values successively. The second and third set of ordinates are advanced by 6 and 12 h respectively and the ordinates at a given time interval added. The base flow is then added to obtain the flood hydrograph shown in Col 8, Table 6.6. Interval Rainfall depth (cm) Loss @ 0.25 cm/h for 6 h Effective rainfall (cm)

1st 6 hours

2nd 6 hours

3rd 6 hours

3.5 1.5 2.0

(11.0 – 3.5) = 7.5 1.5 6.0

(16.5 – 11.0) = 5.5 1.5 4.0

Table 6.5 Calculation of Flood Hydrograph due to a known ERH—Example 6.6 Time Ordinates DRH due of UH to 2 cm ER Col. 2 ´ 2.0

1

2

3

0 3 6 9 12 15 18 (21) 24 (27) 30 36 42 48 54 60 66 69 72 75 78 81 84

0 25 50 85 125 160 185 (172.5) 160 (135) 110 60 36 25 16 8 (2.7) 0

0 50 100 170 250 320 370 (345) 320 (270) 220 120 72 50 32 16 (5.4) 0 0 0 0

DRH due DRH due Ordinates Base Ordinates to 2 cm to 4 cm of final flow of flood hydroER ER DRH (m3/s) Col. 2 Col. 2 (Col. 3 + graph ´ 6.0 ´ 4.0 4 + 5) (m3/s) (Advanced (Advanced (Col. 6 by 6 h) by 12 h) + 7) 4 0 0 0 150 300 510 750 960 1110 (1035) 960 660 360 216 150 96 48 — 16 0 0

5 0 0 0 0 0 100 200 340 500 640 740 640 440 240 144 100 64 — 32 — (10.8) 0

6 0 50 100 320 550 930 1320 1645 1930 1945 1920 1420 872 506 326 212 117 — 48 — (11) 0

7 ]5 15 15 15 17 17 17 (17) 19 19 19 21 21 23 23 25 25 — 27 — 27 27 27

8 15 65 115 335 567 947 1337 1662 1949 1964 1939 1441 893 529 349 237 142 — 75 — 49 27 27

Note: Due to the unequal time intervals of unit hydrograph ordinates, a few entries, indicated in parentheses have to be interpolated to complete the table.

212 Engineering Hydrology

6.7 DERIVATION OF UNIT HYDROGRAPHS A number of isolated storm hydrographs caused by short spells of rainfall excess, each of approximately same duration [0.90 to 1.1 D h] are selected from a study of the continuously gauged runoff of the stream. For each of these storm hydrographs, the base flow is separated by adopting one of the methods indicated in Sec. 6.4. The area under each DRH is evaluated and the volume of the direct runoff obtained is divided by the catchment area to obtain the depth of ER. The ordinates of the various DRHs are divided by the respective ER values to obtain the ordinates of the unit hydrograph. Flood hydrographs used in the analysis should be selected to meet the following desirable features with respect to the storms responsible for them. l The storms should be isolated storms occurring individually. l The rainfall should be fairly uniform during the duration and should cover the entire catchment area. l The duration of the rainfall should be 1/5 to 1/3 of the basin lag. l The rainfall excess of the selected storm should be high. A range of ER values of 1.0 to 4.0 cm is sometimes preferred. A number of unit hydrographs of a given duration are derived by the above method and then plotted on a common pair of axes as shown in Fig. 6.12. Due to the rainfall variations both in space and time and due to storm departures from the assumptions of the unit hydrograph theory, the various unit hydrographs thus developed will not be identical. It is a common practice to adopt a mean of such curves as the unit hydrograph of a given duration for the catchment. While deriving the mean curve, the average of peak flows and time to peaks are first calculated. Then a mean curve of best fit, judged by eye, is drawn through the averaged peak to close on an averaged base length. The volume of DRH is calculated and any departure from unity is corrected by adjusting the value of the peak. The averaged ERH of unit depth is customarily drawn in the plot of the unit hydrograph to indicate the type and duration of rainfall causing the unit hydrograph.

Fig. 6.12 Derivation of an Average Unit Hydrograph

Hydrographs

213

By definition the rainfall excess is assumed to occur uniformly over the catchment during duration D of a unit hydrograph. An. ideal duration for a unit hydrograph is one wherein small fluctuations in the intensity of rainfall within this duration do not have any significant effect on the runoff. The catchment has a damping effect on the fluctuations of the rainfall intensity in the runoff-producing process and this damping is a function of the catchment area. This indicates that larger durations are admissible for larger catchments. By experience it is found that the duration of the unit hydrograph should not exceed 1/5 to 1/3 basin lag. For catchments of sizes larger than 250 km2 the duration of 6 h is generally satisfactory. EXAMPLE 6.7 Following are the ordinates of a storm hydrograph of a river draining a catchment area of 423 km2 due to a 6-h isolated storm. Derive the ordinates of a 6-h unit hydrograph for the catchment Time from start of storm (h) Discharge (m3/s)

–6 10

Time from start of storm (h) Discharge (m3/s)

54 60 66 72 78 84 90 96 102 39.0 31.5 26.0 21.5 17.5 15.0 12.5 12.0 12.0

0 10

6 30

12 18 24 30 36 42 48 87.5 115.5 102.5 85.0 71.0 59.0 47.5

SOLUTION: The flood hydrograph is plotted to scale (Fig. 6.13). Denoting the time from beginning of storm as t, by inspection of Fig. 6.12,

Fig. 6.13 Derivation of Unit Hydrograph from a flood Hydrograph

214 Engineering Hydrology A = beginning of DRH B = end of DRH Pm = peak

Hence

t=0 t = 90 h t = 20 h

N = (90 – 20) = 70 h = 2.91 days

By Eq. (6.4),

N = 0.83 (423)0.2 = 2.78 days However, N = 2.91 days is adopted for convenience. A straight line joining A and B is taken as the divide line for base-flow separation. The ordinates of DRH are obtained by subtracting the base flow from the ordinates of the storm hydrograph. The calculations are shown in Table 6.6. Volume of DRH = 60 ´ 60 ´ 6 ´ (sum of DRH ordinates) = 60 ´ 60 ´ 6 ´ 587 = 12.68 Mm3 Drainage area = 423 km2 = 423 Mm2 12.68 Runoff depth = ER depth = = 0.03 m = 3 cm. 423 The ordinates of DRH (col. 4) are divided by 3 to obtain the ordinates of the 6-h unit hydrograph (see Table 6.6).

Table 6.6

Calculation of the Ordinates of a 6-H Unit Hydrograph— Example 6.7

Time from beginning of storm (h)

Ordinate of flood hydrograph (m3/s)

Base Flow (m3/s)

Ordinate of DRH (m3/s)

Ordinate of 6-h unit hydrograph (Col. 4)/3

1

2

3

4

5

–6 0 6 12 18 24 30 36 42 48 54 60 66 72 78 84 90 96 102

10.0 10.0 30.0 87.5 111.5 102.5 85.0 71.0 59.0 47.5 39.0 31.5 26.0 21.5 17.5 15.0 12.5 12.0 12.0

10.0 10.0 10.0 10.5 10.5 10.5 11.0 11.0 11.0 11.5 11.5 11.5 12.0 12.0 12.0 12.5 12.5 12.0 12.0

0 0 20.0 77.0 101.0 101.0 74.0 60.0 48.0 36.0 27.5 20.0 14.0 9.5 5.5 2.5 0 0 0

0 0 6.7 25.7 33.7 33.7 24.7 20.0 16.0 12.0 9.2

Hydrographs

215

EXAMPLE 6.8 (a) The peak of flood hydrograph due to a 3-h duration isolated storm in a catchment is 270 m3/s. The total depth of rainfall is 5.9 cm. Assuming an average infiltration loss of 0.3 cm/h and a constant base flow of 20 m3/s, estimate the peak of the 3-h unit hydrograph (UH) of this catchment. (b) If the area of the catchment is 567 km2 determine the base width of the 3-h unit hydrograph by assuming it to be triangular in shape. SOLUTION:

(a) Duration of rainfall excess = 3 h Loss @ 0.3 cm/h for 3 h = 0.9 cm Total depth of rainfall = 5.9 cm Rainfall excess = 5.9–0.9 = 5.0 cm Peak flow: Peak of flood hydrograph = 270 m3/s Peak of DRH = 250 m3/s Base flow = 20 m3/s peak of DRH 250 = = 50 m3/s Peak of 3-h unit hydrograph = rainfall excess 5.0 (b) Let B = base width of the 3-h UH in hours. Volume represented by the area of UH = volume of 1 cm depth over the catchment Area of UH = (Area of catchment ´ 1 cm) 1 1 ´ B ´ 60 ´ 60 ´ 50 = 567 ´ 106 ´ 2 100 567 ´ 104 B= = 63 hours. 9 ´ 104

Unit Hydrograph from a Complex Storm When suitable simple isolated storms are not available, data from complex storms of long duration will have to be used in unit-hydrograph derivation. The problem is to decompose a measured composite flood hydrograph into its component DRHs and base flow. A common unit hydrograph of appropriate duration is assumed to exist. This problem is thus the inverse of the derivation of flood hydrograph through use of Eq. (6.5). Consider a rainfall excess made up of three consecutive durations of D-h and ER values of R1, R2 and R3. Figure 6.14 shows the ERR. By base flow separation of the resulting composite flood hydrograph a composite DRH is obtained (Fig. 6.14). Let the ordinates of the composite DRH be drawn at a time interval of D-h. At various time intervals 1D, 2D, 3D, … from the start of the ERH, let the ordinates of the unit hydrograph be u1, u2, u3, … and the ordinates of the composite DRH be Q1, Q2, Q3, …, Then Q1 = R1 u1 Fig. 6.14 Unit hydrograph from a Q2 = R1 u2 + R2 u1 Complex Storm Q3 = R1 u3 + R2 u2 + R3 u1

216 Engineering Hydrology Q4 = R1 u4 + R2 u3 + R3 u2 Q5 = RI u5 + R2 u4 + R3 u3 . . . . . . . . . . . . . .

(6.6) so on. From Eq. (6.6) the values of u1, u2, u3, … can be determined. However, this method suffers from the disadvantage that the errors propagate and increase as the calculations proceed. In the presence of errors the recession limb of the derived D-h unit hydrograph can contain oscillations and even negative values. Matrix methods with optimisation schemes are available for solving Eq. (6.6) in a digital computer.

6.8 UNIT HYDROGRAPHS OF DIFFERENT DURATIONS Ideally, unit hydrographs are derived from simple isolated storms and if the duration of the various storms do not differ very much, say within a band of ± 20% D, they would all be grouped under one average duration of D-h. If in practical applications unit hydrographs of different durations are needed they are best derived from field data. Lack of adequate data normally precludes development of unit hydrographs covering a wide range of durations for a given catchment. Under such conditions a D hour unit hydrograph is used to develop unit hydrographs of differing durations nD. Two methods are available for this purpose. l Method of superposition l The S-curve These are discussed below.

Method of Superposition If a D-h unit hydrograph is available, and it is desired to develop a unit hydrograph of nD h, where n is an integer, it is easily accomplished by superposing n unit hydrographs with each graph separated from the previous on by D-h. Figure 6.15 shows three 4-h unit hydrographs A, B and C. Curve B begins 4 h after A and C begins 4-h, after B. Thus the combination of these three curves is a DRH of 3 cm due to an ER of 12-h duration. If the ordinates of this DRH are now divided by 3, one obtains a 12-h unit hydrograph. The calculations are easy if performed in a tabular form (Table 6.7). EXAMPLE 6.9 Given the ordinates of a 4-h unit hydrograph as below derive the ordinates of a 12-h unit hydrograph for the same catchment. Time (h) Ordinate of 4-h UH

0 0

4 20

8 12 16 20 80 130 150 130

24 90

28 52

32 27

36 15

40 5

44 0

SOLUTION: The calculations are performed in a tabular form in Table 6.7. In this

Column 3 = ordinates of 4-h UH lagged by 4-h Column 4 = ordinates of 4-h UH lagged by 8-h Column 5 = ordinates of DRH representing 3 cm ER in 12-h Column 6 = ordinates of 12-h UH = (Column 5)/3 The 12-h unit hydrograph is shown in Fig. 6.15.

The S-Curve If it is desired to develop a unit hydrograph of duration mD, where m is a fraction, the method of superposition cannot be used. A different technique known as the S-curve method is adopted in such cases, and this method is applicable for rational values of m.

217

Hydrographs

Table 6.7

Calculation of a 12-h Unit Hydrograph from a 4-H Unit Hydrograph—Example 6.9

Time (h)

1 0 4 8 12 16 20 24 28 32 36 40 44 48 52

Fig. 6.15

Ordinates of 4-h UH (m3/s) A B C Lagged by Lagged by 4-h 8-h 2 0 20 80 130 150 130 90 52 27 15 5 0

DRH Ordinate of of 3 cm in 12-h UH 12-h (m3/s) 3 (Col. 5)/3 (m /s) (Col. 2+3+4)

3

4

5

6

— 0 20 80 130 150 130 90 52 27 15 5 0

— — 0 20 80 130 150 130 90 52 27 15 5 0

0 20 100 230 360 410 370 272 169 94 47 20 5 0

0 6.7 33.3 76.7 120.0 136.7 123.3 90.7 56.3 31.3 15.7 6.7 1.7 0

Construction of a 12-h Unit Hydrograph from a 4-h Unit Hydrograph—Example 6.9

218 Engineering Hydrology The S-curve, also known as S-hydrograph is a hydrograph produced by a continuous effective rainfall at a constant rate for an infinite period. It is a curve obtained by summation of an infinite series of D-h unit hydrographs spaced D-h apart. Figure 6.16 shows such a series of D-h hydrograph arranged with their starting points D-h apart. At any given time the ordinates of the various curves occurring at that time coordinate are summed up to obtain ordinates of the S-curve. A smooth curve through these ordinates result in an S-shaped curve called S-curve.

Fig. 6.16 S-curve This S-curve is due to a D-h unit hydrograph. It has an initial steep portion and reaches a maximum equilibrium discharge at a time equal to the time base of the first unit hydrograph. The average intensity of ER producing the S-curve is 1/D cm/h and the equilibrium discharge, A Qs = æ ´ 104 ö m3/h, èD ø where A = area of the catchment in km2 and D = duration in hours of ER of the unit hydrograph used in deriving the S-curve. Alternatively A (6.7) Qs = 2.778 m3/s D where A is the km2 and D is in h. The quantity Qs represents the maximum rate at which an ER intensity of 1/D cm/h can drain out of a catchment of area A. In actual

Hydrographs

219

construction of an S-curve, it is found that the curve oscillates in the top portion at around the equilibrium value due to magnification and accumulation of small errors in the hydrograph. When it occurs, an average smooth curve is drawn such that it reaches a value Qs at the time base of the unit hydrograph. [Note: It is desirable to designate the S-curve due to D-hour unit hydrograph as SDcurve to give an indication that the average rainfall excess of the curve is (1/D) cm/h. It is particularly advantageous when more than one S-curve is used as in such cases the curves would be designated as SD1, SD2, … etc. to avoid possible confusion and mistakes.] Construction of S–curve By definition an S-curve is obtained by adding a string of D-h unit hydrographs each lagged by D-hours from one another. Further, if Tb = base period of the unit hydrograph, addition of only Tb/D unit hydrographs are sufficient to obtain the S-curve. However, an easier procedure based on the basic property of the S-curve is available for the construction of S-curves. i.e. U(t) = S(t) – S(t–D) or S(t) = U(t) + S(t–D) (6.8) The term S(t–D) could be called S-curve addition at time t so that Ordinate of S-curve at any time t = Ordinate of D-h unit hydrograph at time t + S-curve addition at time t Noting that for all t £ D, S(t-D) = 0, Eq. (6.8) provides a simple recursive procedure for computation of S-curve ordinates. The procedure is explained in Example 6.10. EXAMPLE 6.10 Derive the S-curve for the 4-h unit hydrograph given below. Time (h) Ordinate of 4-h UH (m3/s)

0 0

4 10

8 30

12 25

16 18

20 10

24 5

28 0

SOLUTION: Computations are shown in Table 6.8. In this table col. 2 shows the ordinates of the 4-h unit hydrograph. col. 3 gives the S-curve additions and col. 4 gives the ordinates of the S-curve. The sequence of entry in col. 3 is shown by arrows. Values of entries in col. 4 is obtained by using Eq. (6.8), i.e. by summing up of entries in col. 2 and col. 4 along each row. Table 6.8 Construction of S-curve—Example 6.10 Time in hours

Ordinate of 4-h UH

S-curve addition (m3/s)

S4-curve ordinate (m3/s). (col. 2 + col. 3)

1

2

3

4

0 4 8 12 16 20 24 28

0 10 30 25 18 10 5 0

0 10 40 65 83 93 98

0 10 40 65 83 93 98 98

220 Engineering Hydrology At i = 4 hours; Ordinate of 4-hUH = 10 m3/s. S-curve addition = ordinate of 4-h UH @{t = (4–4) ¹ 0 hours} = 0 Hence S-curve ordinate Eq. (6.8) = 10 + 0 = 10 m3/s, At t = 8 hours; Ordinate of 4-hUH = 30 m3/s. S-curve addition = ordinate of 4-hUH @{t = (8–4) = 4 hours} = 10 m3/s Hence S-curve ordinate by Eq. (6.8) = 30 + 10 = 40 m3/s. At t = 12 hours; Ordinate of 4-hUH = 25 m3/s. S-curve addition = ordinate of 4-hUH @{t = (12–4) = 48 hours} = 40 m3/s Hence S-curve ordinate by Eq. (6.8) = 25 + 40 = 65 m3/s. This calculation is repeated for all time intervals till t = base width of UH = 28 hours. Plots of the 4-h UH and the derived S-curve are shown in Fig. 6.17.

Fig. 6.17 Construction of S4-curve—(Example 6.10)

Derivation of T-hour Unit Hydrograph Consider two D-h S-curves A and B displaced by T-h (Fig. 6.18). If the ordinates of B are subtracted from that of A, the resulting curve is a DRH produced by a rainfall

Fig. 6.18 Derivation of a T-h Unit Hydrograph by S-curve Lagging Method

221

Hydrographs

1 excess of duration T-h and magnitude æ ´ T ö cm. Hence if the ordinate differences èD ø of A and B, i.e. (SA – SB) are divided by T/D, the resulting ordinates denote a hydrograph due to an ER of 1 cm and of duration T-h, i.e. a T-h unit hydrograph. The derivation of a T-h unit hydrograph as above can be achieved either by graphical means or by arithmetic computations in a tabular form as indicated in Example 6.11. EXAMPLE 6.11 Solve Example 6.9 by the S-Curve method. SOLUTION: Computations are shown in Table 6.9. Column 2 shows the ordinates of the

4-h unit hydrograph. Column 3 gives the S-curve additions and Column 4 the S-curve ordinates. The sequence of additions are shown by arrows. At t = 4 h, ordinate of the 4-h UH = ordinate of the S-curve. This value becomes the S-curve addition at t = 2 ´ 4 = 8 h. At this t = 8 h, the ordinate of UH (80) + S-curve addition (20) = S-curve ordinate (100). The S-curve addition at 3 ´ 4 = 12 h is 100, and so on. Column 5 shows the S-curve lagged by 12 h. Column 6 gives the ordinate of DRH of (T/D) = 3 cm. Ordinates shown in Column 6 are divided by (T/D = 3) to obtain the ordinates of the 12-h unit hydrograph shown in Column 7.

Table 6.9

Determination of a 12-H Unit Hydrograph by S-Curve Method—Example 6.11

Time (h)

Ordinate of 4-h UH (m3/s)

S-curve addition (m3/s)

S-curve ordinate (m3/s) (Col. 2 + Col. 3)

S-curve lagged by 12 h (m3/s)

(Col. 4– Col. 5)

Col. 6 = (12/4) 12-h UH ordinates (m3/s)

1

2

3

4

5

6

7

0 4 8 12 16 20 24 28 32 36 40 44 48 52

0 20 80 130 150 130 90 52 27 15 5 0

— 0 20 100 230 380 510 600 652 679 694 699 699

0 20 100 230 380 510 600 652 679 694 699 699 699 699

— — — 0 20 100 230 380 510 600 652 679 694 699

0 20 100 230 360 410 370 272 169 94 47 20 5 0

0 6.7 33.3 76.7 120.0 136.7 123.3 90.7 56.3 31.3 15.7 6.7 1.7 0

EXAMPLE 6.12 Ordinates of a 4-h unit hydrograph are given. Using this derive the ordinates of a 2-h unit hydrograph for the same catchment. Time (h) Ordinate or 4-h UH (m3/s)

0 0

4 20

8 80

12 16 20 130 150 130

24 90

28 52

32 27

36 15

40 5

44 0

222 Engineering Hydrology SOLUTION: In this case the time interval of the ordinates of the given unit hydrograph should be at least 2 h. As the given ordinates are at 4-h intervals, the unit-hydrograph is plotted and its ordinates at 2-h intervals determined. The ordinates are shown in column 2 of Table 6.10. The S-curve additions and S-curve ordinates are shown in columns 3 and 4 respectively. First, the S-curve ordinates corresponding to the time intervals equal to successive durations of the given unit hydrograph (in this case at 0, 4, 8, 12 … h) are determined by following the method of Example 6.11. Next, the ordinates at intermediate intervals (viz. at t = 2, 6, 10, 14 … h) are determined by having another series of S-curve additions. The sequence of these are shown by distinctive arrows in Table 6.9. To obtain a 2-h unit hydrograph the S-curve is lagged by 2 h (column 5) and this is subtracted from column 4 and the results listed in column 6. The ordinates in column 6 are now divided by T/D = 2/4 = 0.5, to obtain the required 2-h unit hydrograph ordinates, shown in column 7. Table 6.10 Determination of 2-h Unit Hydrograph from A 4-h Unit Hydrograph—Example 6.12 Time (h)

Ordinate of 4-h UH (m3/s)

S-curve addition (m3/s)

S-curve ordinate (Col. (2) + (3)) (m3/s)

S-curve lagged by 2h

1

2

3

4

5

6

0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44

0 8 20 43 80 110 130 146 150 142 130 112 90 70 52 38 27 20 15 10 5 2 0

— 0 8 20 51 100 161 230 307 380 449 510 561 600 631 652 669 679 689 694 699 699 701

0 8 12 31 49 61 69 77 73 69 61 51 39 31 21 17 10 10 5 5 (0) (2) (–2)

— — 0 8 20 51 100 161 230 307 380 449 510 561 600 631 652 669 679 689 694 699 699

0 8 20 51 100 161 230 307 380 449 510 561 600 631 652 669 679 689 694 699 699 701 699

Final adjusted values are given in col. 7. Unadjusted values are given in parentheses.

(Col. (4) – Col. (5)) DRH of

2-h UH ordinates Col. (6) (2/4) æ 2 ö = 0.5 cm (m3/s) çè ÷ø 4 7 0 16 24 62 98 122 138 154 146 138 122 102 78 62 42 34 20 (20)15 (10)10 (10)6 (0)3 (4)0 (–4)0

Hydrographs

223

The errors in interpolation of unit hydrograph ordinates often result in oscillation of S-curve at the equilibrium value. This results in the derived T-h unit hydrograph having an abnormal sequence of discharges (sometimes even negative values) at the tail end. This is adjusted by fairing the S-curve and also the resulting T-h unit-hydrograph by smooth curves. For example, in the present example the 2-h unit hydrograph ordinates at time > 36-h are rather abnormal. These values are shown in parentheses. The adjusted values are entered in column 7.

6.9 USE AND LIMITATIONS OF UNIT HYDROGRAPH As the unit hydrographs establish a relationship between the ERH and DRH for a catchment, they are of immense value in the study of the hydrology of a catchment. They are of great use in (i) the development of flood hydrographs for extreme rainfall magnitudes for use in the design of hydraulic structures, (ii) extension of flood-flow records based on rainfall records, and (iii) development of flood forecasting and warning systems based on rainfall. Unit hydrographs assume uniform distribution of rainfall over the catchment. Also, the intensity is assumed constant for the duration of the rainfall excess. In practice, these two conditions are never strictly satisfied. Non-uniform areal distribution and variation in intensity within a storm are very common. Under such conditions unit hydrographs can still be used if the areal distribution is consistent between different storms. However, the size of the catchment imposes an upper limit on the applicability of the unit hydrograph. This is because in very large basins the centre of the storm can vary from storm to storm and each can give different DRHs under otherwise identical situations. It is generally felt that about 5000 km2 is the upper limit for unit-hydrograph use. Flood hydrographs in very large basins can be studied by dividing them into a number of smaller subbasins and developing DRHs by the unit-hydrograph method. These DRHs can then be routed through their respective channels to obtain the composite DRH at the basin outlet. There is a lower limit also for the application of unit hydrographs. This limit is usually taken as about 200 ha. At this level of area, a number of factors affect the rainfall-runoff relationship and the unit hydrograph is not accurate enough for the prediction of DRH. Other limitations to the use of unit hydrographs are: l Precipitation must be from rainfall only. Snow-melt runoff cannot be satisfactory represented by unit hydrograph. l The catchment should not have unusually large storages in terms of tanks, ponds, large flood-bank storages, etc. which affect the linear relationship between storage and discharge. l If the precipitation is decidedly nonuniform, unit hydrographs cannot be expected to give good results. In the use of unit hydrographs very accurate reproduction of results should not be expected. Variations in the hydrograph base of as much as ±20% and in the peak discharge by ±10% are normally considered acceptable.

6.10 DURATION OF THE UNIT HYDROGRAPH The choice of the duration of the unit hydrograph depends on the rainfall records. If recording raingauge data are available any convenient time depending on the size of

224 Engineering Hydrology the basin can be used. The choice is not much if only daily rainfall records are available. A rough guide for the choice of duration D is that it should not exceed the least of (i) the time of rise, (ii) the basin lag, and (iii) the time of concentration. A value of D equal to about 1/4 of the basin lag is about the best choice. Generally, for basins with areas more than 1200 km2 a duration D = 12 hours is preferred.

6.11 DISTRIBUTION GRAPH The distribution graph introduced by Bernard (1935) is a variation of the unit hydrograph. It is basically a D-h unit hydrograph with ordinates showing the percentage of the surface runoff occurring in successive periods of equal time intervals of D-h. The duration of the rainfall excess (D-h) is taken as the unit interval and distribution-graph ordinates are indicated at successive Fig. 6.19 Four-hour Distribution Graph such unit intervals. Figure 6.19 shows a typical 4-h distribution graph. Note the ordinates plotted at 4-h intervals and the total area under the distribution graph adds up to 100%. The use of the distribution graph to generate a DRH for a known ERH is exactly the same as that of a unit hydrograph (Example 6.13). Distribution graphs are useful in comparing the runoff characteristics of different catchments. EXAMPLE 6.13 A catchment of 200 hectares area has rainfalls of 7.5 cm, 2.0 cm and 5.0 cm in three consecutive days. The average f index can be assumed to be 2.5 cm/day. Distribution-graph percentages of the surface runoff which extended over 6 days for every rainfall of 1-day duration are 5, 15, 40, 25, 10 and 5. Determine the ordinates of the discharge hydrograph by neglecting the base flow. SOLUTION: The calculations are performed in a tabular form in Table 6.11. Table 6.11 Calculation of DRH using Distribution Graph—Example 6.13 Time Rain- Infiltrainterval fall tion loss (days) (cm) (cm)

0–1 1–2 2–3

7.5 2.0 5.0

2.5 2.5 2.5

Effective Average Distributed rainfall distri- runoff for rain(cm) buition fall excess of ratio 5 cm 0 2.5 cm (percent) 5.0 0 2.5

5 15 40

0.250 0.750 2.000

0 0 0

0 0.125

Runoff cm

m3/s ´ 10–2

0.250 5.79 0.750 17.36 2.750 49.19 (Contd.)

Hydrographs

(Contd.) 3–4 4–5 5–6 6–7 7–8 8–9

25 10 5 0

1.250 0.500 0.250 0

0 0 0 0 0

0.375 1.000 0.625 0.250 0.125 0

225

2.125 37.62 1.625 34.72 1.500 20.25 0.875 5.79 0.250 2.89 0.125 0

200 ´ 100 ´ 100

m3/s for 1 day = 0.23148 m3/s for 1 day] 86400 ´ 100 (The runoff ordinates are plotted at the mid-points of the respective time intervals to obtain the DRH)

[Runoff of 1 cm in 1 day =

6.12 SYNTHETIC UNIT HYDROGRAPH Introduction To develop unit hydrographs to a catchment, detailed information about the rainfall and the resulting flood hydrograph are needed. However, such information would be available only at a few locations and in a majority of catchments, especially those which are at remote locations, the data would normally be very scanty. In order to construct unit hydrographs for such areas, empirical equations of regional validity which relate the salient hydrograph characteristics to the basin characteristics are available. Unit hydrographs derived from such relationships are known as synthetic-unit hydrographs. A number of methods for developing synthetic-unit hydrographs are reported in literature. It should, however, be remembered that these methods being based on empirical correlations are applicable only to the specific regions in which they were developed and should not be considered as general relationships for use in all regions.

Snyder’s Method Snyder (1938), based on a study of a large number of catchments in the Appalachian Highlands of eastern United States developed a set of empirical equations for synthetic-unit hydrographs in those areas. These equations are in use in the USA, and with some modifications in many other countries, and constitute what is known as Snyder’s synthetic-unit hydrograph. The most important characteristic of a basin affecting a hydrograph due to a storm is basin lag. While actually basin lag (also known as lag time) is the time difference between the centroid of the input (rainfall excess) and the output (direct runoff hydrograph), because of the difficulty in determining the centroid of the direct runoff hydrograph (DRH) it is defined for practical purposes as the elapsed time between the centroid of rainfall excess and peak of DRH. Physically, lag time represents the mean time of travel of water from all parts of the watershed to the outlet during a given storm. Its value is determined essentially on the topographical features, such as the size, shape, stream density, length of main stream, slope, land use and land cover. The modified definition of basin time is very commonly adopted in the derivation of synthetic unit hydrographs for a given watershed.

226 Engineering Hydrology The first of the Snyder’s equation relates the basin lag tp, defined as the time interval from the mid-point of rainfall excess to the peak of the unit hydrograph (Fig. 6.20), to the basin characteri-stics as (6.9) tp = Ct(LLca)0.3 where tp = basin lag in hours L = basin length measured along the water course from the basin divide Fig. 6.20 Elements of a Synthetic Unit to the gauging station Hydrograph in km Lca = distance along the main water course from the gauging station to a point opposite to the watershed centroid in km Ct = a regional constant representing watershed slope and storage effects. The value of Ct in Snyder’s study ranged from 1.35 to 1.65. However, studies by many other investigators have shown that Ct depends upon the region under study and wide variations with the value of Ct ranging from 0.3 to 6.0 have been reported6. Linsley et al.5 found that the basin lag tp is better correlated with the catchment æ LLca ö parameter ç ÷ where S = basin slope. Hence, a modified form of Eq. (6.9) was è S ø suggested by them as n

æ LLca ö tp = CtL ç (6.10) ÷ è S ø where CtL and n are basin constants. For the basins in the USA studied n by them n was found to be equal to 0.38 and the values of CtL were 1.715 for mountainous n drainage areas, 1.03 for foot-hill drainage areas and 0.50 for valley drainage areas. Snyder adopted a standard duration tr hours of effective rainfall given by tp (6.11) tr = 5.5 The peak discharge Qps (m3/s) of a unit hydrograph of standard duration tr h is given by Snyder as 2.78 C p A (6.12) Qps = tp where A = catchment area in km2 and Cp = a regional constant. This equation is based on the assumption that the peak discharge is proportional to the average discharge of æ 1 cm ´ catchment area ö çè duration of rainfall excess ÷ø . The values of the coefficient Cp range from 0.56 to 0.69 for Snyder’s study areas and is considered as an indication of the retention and storage capacity of the watershed. Like Ct, the values of Cp also vary quite considerably

Hydrographs

227

depending on the characteristics of the region and values of Cp in the range 0.31 to 0.93 have been reported. If a non-standard rainfall duration tR h is adopted, instead of the standard value tr to derive a unit hydrograph the value of the basin lag is affected. The modified basin lag is given by t -t tR 21 tp + (6.13) t p¢ = tp + R r = 4 22 4 where t p¢ = basin lag in hours for an effective duration of tR h and tp is as given by Eq. (6.9) or (6.10). The value of t p¢ must be used instead of tp in Eq. (6.11). Thus the peak discharge for a nonstandard ER of duration tR is in m3/s (6.12a) Qp = 2.78 Cp A/ t p¢ Note that when tR = tr Qp = Qps The time base of a unit hydrograph (Fig. 6.20) is given by Synder as t p¢ days = (72 + 3 t p¢ ) hours (6.14) Tb = 3 + 8 where Tb = time base. While Eq. (6.14) gives reasonable estimates of Tb for large catchments, it may give excessively large values of the time base for small catchments. Taylor and Schwartz1 recommend tR ö æ Tb = 5 ç t p¢ + ÷ hours (6.15) 2ø è with tb (given in h) taken as the next larger integer value divisible by tR, i.e. Tb is about five times the time-to-peak. To assist in the sketching of unit hydrographs, the widths of unit hydrographs at 50 and 75% of the peak (Fig. 6.20) have been found for US catchments by the US Army Corps of Engineers. These widths (in time units) are correlated to the peak discharge intensity and are given by 5.87 W50 = (6.16) q1.08 (6.17) and W75 = W50/1.75 where W50 = width of unit hydrograph in h at 50% peak discharge W75 = width of unit hydrograph in h at 75% peak discharge q = Qp/A = peak discharge per unit catchment area in m3/s/km2 Since the coefficients Ct and Cp vary from region to region, in practical applications it is advisable that the value of these coefficients are determined from known unit hydrographs of a meteorologically homogeneous catchment and then used in the basin under study. This way Snyder’s equations are of use in scaling the hydrograph information from one catchment to another similar catchment.

EXAMPLE 6.14 Two catchments A and B are considered meteorologically similar. Their catchment characteristics are given below.

228 Engineering Hydrology Catchment A

Catchment B

L = 30 km Lca = 15 km A = 250 km2

L = 45 km Lca = 25 km A = 400 km2

For catchment A, a 2-h unit hydrograph was developed and was found to have a peak discharge of 50 m3/s. The time to peak from the beginning of the rainfall excess in this unit hydrograph was 9.0 h. Using Snyder’s method, develop a unit hydrograph for catchment B.

SOLUTION: For Catchment A:

tR = 2.0 h Time to peak from beginning of ER tR Tp = + t p¢ = 9.0 h 2 \ t p¢ = 8.0 h From Eq. (6.13), tR 21 21 = tp + t p + 0.5 = 8.0 22 4 22 7.5 ´ 22 = 7.857 h tp = 21

t p¢ =

From Eq. (6.9),

tp = Ct(L Lca)0.3 From Eq. (6.12a), Qp = 2.78 Cp A/ t p¢

7.857 = Ct(30 ´ 15)0.3

Ct = 1.257

50 = 2.78 ´ Cp ´ 250/8.0

Cp = 0.576

For Catchment B: Using the values of Ct = 1.257 and Cp = 0.576 in catchment B, the parameters of the synthetic-unit hydrograph for catchment B are determined. From Eq. (6.9), tp = 1.257 (45 ´ 25)0.3 = 10.34 h By Eq. (6.11), 10.34 tr = = 1.88 h 5.5 Using tR = 2.0 h, i.e. for a 2-h unit hydrograph, by Eq. (6.12), t p¢ = 10.34 ´

21 2.0 = 10.37 h + 22 4

By Eq. (6.12a), Qp = From Eq. (6.16),

2.78 ´ 0.576 ´ 400 10.37

= 61.77 m3/s, say 62 m3/s

W50 =

5.87 = 44 h (62/400)1.08

W75 =

44 = 25 h 1.75

By Eq. (6.17),

Hydrographs

229

Time base: From Eq. (6.14), Tb = 72 + (3 ´ 10.37) = 103 h From Eq. (6.14), Tb = 5 (10.37 + 10) » 58 h Considering the values of W50 and W75 and noting that the area of catchment B is rather small, Tb » 58 h is more appropriate in this case.

Finalizing of Synthetic-Unit Hydrograph After obtaining the values of Qp, tR, t p¢ , W75, W50 and Tb from Snyder’s equations, a tentative unit hydrograph is sketched and S-curve is then developed and plotted. As the ordinates of the unit hydrograph are tentative, the S-curve thus obtained will have kinks. These are then smoothened and a logical pattern of the S-curve is sketched. Using this S-curve tR hour unit hydrograph is then derived back. Further, the area under the unit hydrograph is checked to see that it represents 1 cm of runoff. The procedure of adjustments through the S-curve is repeated till satisfactory results are obtained. It should be noted that out of the various parameters of the synthetic unit hydrograph the least accurate will be the time base Tb and this can be changed to meet other requirements.

SCS Dimensionless Unit Hydrograph Dimensionless unit hydrographs based on a study of a large number of unit hydrographs are recommended by various agencies to facilitate construction of synthetic unit hydrographs. A typical dimensionless unit hydrograph developed by the US Soil Conservation Services (SCS) is shown in Fig. 6.21(a). In this the ordinate is (Q/Qp) which is the discharge Q expressed as a ratio to the peak discharge Qp, and the abscissa is (t/ Tp), which is the time t expressed as a ratio of the time to peak Tp. By definition, Q/Qp = 1.0 when t/Tp = 1.0. The coordinates of the SCS dimensionless unit hydrograph is given in Table 6.12 for use in developing a synthetic unit hydrograph in place of Snyder’s equations (6.14) through (6.17). Table 6.12 Coordinates of SCS Dimensionless Unit Hydrograph4 t/Tp

Q/Qp

t/Tp

Q/Qp

t/Tp

Q/Qp

0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0

0.000 0.015 0.075 0.160 0.280 0.430 0.600 0.770 0.890 0.970 1.000

1.10 1.20 1.30 1.40 1.50 1.60 1.80 2.00 2.20 2.40 2.60

0.980 0.92 0.840 0.750 0.660 0.560 0.420 0.320 0.240 0.180 0.130

2.80 3.00 3.50 4.00 4.50 5.00

0.098 0.074 0.036 0.018 0.009 0.004

SCS Triangular Unit Hydro-graph The value of Qp and Tp may be estimated using a simplified model of a triangular unit hydrograph (Fig. 6.21(b)) suggested by SCS. This triangular unit hydrograph has the same percentage of volume on the rising side as the dimensionless unit hydrograph of Fig. 6.21(a).

230 Engineering Hydrology

Fig. 6.21(a) Dimensionless SCS Unit Hydrograph In Fig. 6.21(b), Qp = peak discharge in m3/s tr = duration of effective rainfall Tp = time of rise = time to peak = (tr/2) + tp tp = lag time Tb = base length SCS suggests that the time of recession = (Tb – Tp) = 1.67 Tp Thus Tb = 2.67 Tp Since the area under the unit hydrograph is equal to 1 cm, If A = area of the watershed in km2,

Fig. 6.21(b)

SCS Triangular Unit Hydrograph

1 1 Q ´ (2.67Tp) ´ (3600) = ´ A ´ 106 2 F 100 Qp =

2 A ´ 104 A = 2.08 Tp 3600 ´ 2.67T p

(6.18)

Further on the basis of a large number of small rural watesheds, SCS found that tp » 0.6 tc, where tc = time of concentration (described in detail in Sec. 7.2, Chapter 7). Thus

æ tr ö Tp = ç + 0.6 tc ÷ è2 ø

(6.19)

The SCS triangular unit hydrograph is a popular method used in watershed development activities, especially in small watersheds.

Hydrographs

231

EXAMPLE 6.15 Develop a 30 minute SCS triangular unit hydrograph for a watershed of area 550 ha and time of concentration of 50 minutes. SOLUTION: A = 550 ha = 5.5 km2 lag time

tr = 30 min = 0.50 h tc = 50 min = 0.833 h tp = 0.6 tc = 0.6 ´ 0.833 = 0.50 h

æ tr ö Tp = ç + t p ÷ = 0.25 + 0.50 = 0.75 h è 2 ø

A 5.5 = 2.08 ´ = 15.25 m3/s Tp 0.75 Tb = 2.67 Tp = 2.67 ´ 0.75 = 2.00 h

Qp = 2.08

The derived triangular unit hydrograph is shown in Fig. 6.22

Fig. 6.22 Triangular Unit Hydrograph—Example 6.15

The Indian Practice Two approaches (short term plan and long term plan) were adopted by CWC to develop methodologies for estimation of design flood discharges applicable to small and medium catchments (25–1000 ha) of India. Under the short-term plan, a quick method of estimating design flood peak has been developed2 as follows: The peak discharge of a D-h unit hydrograph Qpd in m3/s is Qpd = 1.79A3/4 for Sm > 0.0028 (6.20) 2/3

and Qpd = 37.4A3/4 S m for Sm < 0.0028 2 where A = catchment area in km and Sm = weighted mean slope given by 2

(6.21)

é ù Lca (6.22) Sm = ê ú 1/ 2 1/ 2 1/ 2 êë ( L1 / S1 ) + ( L2 / S2 ) + L + ( Ln / Sn ) úû in which Lca = distance along the river from the gauging station to a point opposite to the centre of gravity of the area.

232 Engineering Hydrology L1, L2, … Ln = length of main channel having slopes SI, S2, … Sn respectively, obtained from topographic maps. The lag time in hours (i.e. time interval from the mid-point of the rainfall excess to the peak) of a 1-h unit hydrograph, tp1 is given by 1.56 tP1 = (6.23) [Q pd / A]0.9 For design purposes the duration of rainfall excess in hours is taken as D = 1.1 tp1 (6.24) Equations (6.20) through (6.22) enable one to determine the duration and peak discharge of a design unit hydrograph. The time to peak has to be determined separately by using Eq. (6.9) or (6.10). Under the long-term plan, a separate regional methodology has been developed by CWC. In this, the country is divided into 26 hydrometeorologically homogeneous subzones. For each subzone, a regional synthetic unit hydrograph has been developed. Detailed reports containing the synthetic unit hydrograph relations, details of the computation procedure and limitations of the method have been prepared, [e.g. CWC Reports No. CB/11/1985 and GP/10/1984 deal with flood estimation in Kaveri Basin (Sub-zone – 3i) and Middle Ganga Plains (Sub-zone – 1f ) respectively.]

6.13 INSTANTANEOUS UNIT HYDROGRAPH (IUH) The unit-hydrograph concept discussed in the preceding sections considered a D-h unit hydrograph. For a given catchment a number of unit hydrographs of different durations are possible. The shape of these different unit hydrographs depend upon the value of D. Figure 6.23 shows a typical variation of the shape of unit hydrographs for different values of D. As D is reduced, the intensity of rainfall excess being equal to 1/D increases and the unit hydrograph becomes more skewed. A finite unit hydrograph is indicated as the duration D ® 0. The limiting case of a unit hydrograph of zero duration is known as instantaneous unit hydrograph (IUH). Thus IUH is a fictitious, conceptual unit hydrograph which represents the surface runoff from the catchment due to

Fig. 6.23 Unit Hydrographs of Different Durations

Hydrographs

233

an instantaneous precipitation of the rainfall excess volume of 1 cm. IUH is designated as u (t) or sometimes as u (0, t). It is a single-peaked hydrograph with a finite base width and its important properties can be listed as below: 1. 0 £ u (t) £ a positive value, for t > 0; 2. u(t) = 0 for t £ 0; 3. u(t) ® = 0 as t ® ¥; 4.

¥

ò u (t) dt = unit depth over the catchment; and

5. time to the peak time to the centroid of the curve. Consider an effective rainfall I (t) of duration t0 applied to a catchment as in Fig. 6.24. Each infinitesimal element of this ERH will operate on the IUH to produce a DRH whose discharge at time t is given by t¢

Q(t) = ò u (t – t) I (t) dt where

t¢ = t when t < t0

and

(6.25) t¢ = t0 when t ³ t0

Fig. 6.24 Convolution of 1 (t) and IUH Equation (6.25) is called the convolution integral or Duhamel integral. The integral of Eq. (6.25) is essentially the same as the arithmetical computation of Eq. (6.5). The main advantage of IUH is that it is independent of the duration of ERH and thus has one parameter less than a D-h unit hydrograph. This fact and the definition of IUH make it eminently suitable for theoretical analysis of rainfall excess-runoff relationship of a catchment. For a given catchment IUH, being independent of rainfall characteristics, is indicative of the catchment storage characteristics.

234 Engineering Hydrology

Derivation of IUH Consider an S-curve, designated as S1, derived from a D-h unit hydrograph. In this the intensity of rainfall excess, i = 1/D cm/h. Let S2 be another S-curve of intensity i cm/ h. If S2 is separated from S1 by a time interval dt and the ordinates are subtracted, a DRH due to a rainfall excess of duration dt and magnitude i dt = dt/D h is obtained. A unit hydrograph of dt hours is obtained from this by dividing the above DRH by i dt. æ S2 - S1 ö . As dt is made Thus the dt-h unit hydrograph will have ordinates equal to ç è i dt ÷ø smaller and smaller, i.e. as dt ® 0, an IUH results. Thus for an IUH, the ordinate at any time t is æ S2 - S1 ö 1 dS u(t) = Lim ç (6.26) = dt ® 0 è i dt ÷ø i dt If i = 1, then u(t) = dS¢/dt, (6.27) where S¢ represents a S-curve of intensity 1 cm/h. Thus the ordinate of an IUH at any time t is the slope of the S-curve of intensity 1 cm/h (i.e. S-curve derived from a unit hydrograph of 1-h duration) at the corresponding time. Equation (6.26) can be used in deriving IUH approximately. IUHs can be derived in many other ways, notably by (i) harmonic analysis (ii) Laplace transform, and (iii) conceptual models. Details of these methods are beyond the scope of this book and can be obtained from Ref. 3. However, two simple models viz., Clark’s model and Nash’s model are described in Chapter 8 (Sections 8.8 and 8.9).

Derivation of D-hour Unit Hydrograph from IUH For simple geometric forms of IUH, Eq. (6.25) can be used to derive a D-hour unit hydrograph. For complex shaped IUHs the numerical computation techniques used in deriving unit hydrographs of different durations (Sec. 6.7) can be adopted. From Eq. 6.27, dS¢ = u(t) dt Integrating between two points 1 and 2 t2

S 2¢ - S1¢ = ò u(t) dt t1

(6.28)

If u(t) is essentially linear within the range 1–2, then for small values of Dt = (t2 – t1), by taking 1 u(t) = u (t) = [u(t1) + u(t2)] 2 1 (6.29) S 2¢ - S1¢ = [u(t1) + u(t2)] (t2 – t1) 2 But ( S 2¢ - S1¢) /(t2 – t1) = ordinate of a unit hydrograph of duration D1 = (t2 – t1). Thus, in general terms, for small values of D1, the ordinates of a D1-hour unit hydrograph are obtained by the equation 1 (6.30) (D1-hour UH)t = [(IUH)t + (IUH )t - D1] 2 Thus if two IUHs are lagged by D1–hour where D1 is small and their corresponding ordinates are summed up and divided by two, the resulting hydrograph will be a D1-hour UH. After obtaining the ordinates of a D-hour unit hydrograph from

Hydrographs

235

Eq. (6.30), the ordinates of any D-hour UH can be obtained by the superposition method or S-curve method described in Sec. 6.7. From accuracy considerations, unless the limbs of IUH can be approximated as linear, it is desirable to confine D1 to a value of 1-hour or less. EXAMPLE 6.16 The coordinates of the IUH of a catchment are given below. Derive the direct runoff hydrograph (DRH) for this catchment due to a storm of duration 4 hours and having a rainfall excess of 5 cm. Time (hours) IUH ordinate u(t) (m3/s)

1

2

3

4

5

6

7

8

9

10

11

12

8

35

50

47

40

31

23

15

10

6

3

SOLUTION: The calculations are performed in Table 6.13.

1. First, the ordinates of 1-h UH are derived by using Eq. (6.30)

In Table 6.13, Col. 2 = ordinates of given IUH = u(t) Col. 3 = ordinates of IUH lagged by 1-h 1 Col. 4 = (Col. 2 + Col. 3) = ordinates of 1-h UH by Eq. (6.30) 2 2. Using the 1-hour UH, the S-curve is obtained and lagging it by 4 hours the ordinates of 4-h UH are obtained. In Table 6.12, Col. 5 = S-curve additions Col. 6 = (Col. 4 + Col. 5) = S-curve ordinates Col. 7 = Col. 6 lagged by 4 hours = S-curve ordinates lagged by 4-h. Col. 8 = (Col. 6 – Col. 7) = Ordinates of a DRH due to 4 cm of ER in 4 hours. Col. 9 = (Col. 8)/4 = Ordinates of 4-hour UH 3. The required DRH ordinates due to 5.0 cm ER in 4 hours are obtained by multiplying the ordinates of 4-h UH by 5.0 In Table 6.12, Co1. 10 = (Col. 9) ´ 5.0 = ordinates of required DRH [Note: Calculation of 4-hour UH directly by using D1 = 4-h in Eq. (6.30) will lead to errors as the assumptions of linearity of u(t) during D1 may not be satisfied.]

REFERENCES 1. Butler, S. C., Engineering Hydrology, Prentice Hall Inc., USA, 1957. 2. Central Water Commission, ‘Estimation of Design Flood Peak’, Report No.1, Flood Estimation Directorate, CWC, New Delhi, India, 1973. 3. Chow, V. T., (Ed.), Handbook of Applied Hydrology, McGraw-Hill, New York, USA, 1964. 4. Gray, D. M., Principles of Hydrology, Water Inf. Center, Huntington, NY, USA, 1970. 5. Linsley, R. K. et al., Hydrology for Engineers, McGraw-Hill, New York, USA, 1958. 6. Sokolov, A. A. et al., Flood Flow Computation, The Unesco Press, Paris, France, 1976.

REVISION QUESTIONS 6.1 6.2 6.3 6.4

List the factors affecting a flood hydrograph. Discuss the role of these factors. Describe the analysis of the recession limb of a flood hydrograph. Explain the term Rainfall Excess (ER). How is ERH of a storm obtained? Why is base flow separated from the flood hydrograph in the process of developing a unit hydrograph? 6.5 What is a unit hydrograph? List the assumptions involved in the unit hydrograph theory.

2

u(t) (m3/s)

0 8 35 50 47 40 31 23 15 10 6 3 0

1

Time (h)

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 0 8 35 50 47 40 31 23 15 10 6 3 0 0 0 0

u(t) lagged by 1 hour

3

0 4.0 21.5 42.5 48.5 43.5 35.5 27.0 19.0 12.5 8.0 4.5 1.5 0.0 0.0 0.0 0.0

([2] + [3])/2

Ordinate of 1-h UH (m3/s)

4

0 4.0 25.5 68.0 116.5 160.0 195.5 222.5 241.5 254.0 262.0 266.5 268.0 268.0 268.0 268.0

S-Curve addition (m3/s)

5

0 4.0 25.5 68.0 116.5 160.0 195.5 222.5 241.5 254.0 262.0 266.5 268.0 268.0 268.0 268.0 268.0

[4] + [5]

S-Curve ordinate (m3/s)

6

0.0 4.0 25.5 68.0 116.5 160.0 195.5 222.5 241.5 254.0 262.0 266.5 268.0

S-Curve lagged by 4 hours (m3/s)

7

0.0 4.0 25.5 68.0 116.5 156.0 170.0 154.5 125.0 94.0 66.5 44.0 26.5 14.0 6.0 1.5 0.0

[6]–[7]

DRH of 4 cm in 4 hours

8

Table 6.13 Determination of DRH from IUH—Example 6.16 10

0.00 1.00 6.38 17.00 29.13 39.00 42.50 38.63 31.25 23.50 16.63 11.00 6.63 3.50 1.50 0.38 0.00

[8]/4

0.00 5.00 31.88 85.00 145.63 195.00 212.50 193.13 156.25 117.50 83.13 55.00 33.13 17.50 7.50 1.88 0.00

[9] ´ 5

Ordinate DRH due to 5 of 4-h UH cm ER in 4 (m3/s) hours (m3/s)

9

236 Engineering Hydrology

237

Hydrographs 6.6 6.7

Describe briefly the procedure of preparing a D-hour unit hydrograph for a catchment. Explain the procedure of using a unit hydrograph to develop the flood hydrograph due to a storm in a catchment. 6.8 Describe the S-curve method of developing a 6-h UH by using 12-h UH of the catchment. 6.9 Explain a procedure of deriving a synthetic unit hydrograph for a catchment by using Snyder’s method. 6.10 What is an IUH? What are its characteristics? 6.11 Explain a procedure of deriving a D-h unit hydrograph from the IUH of the catchment. 6.12 Distinguish between (a) Hyetograph and hydrograph (b) D-h UH and IUH

PROBLEMS 6.1 The flood hydrograph of a small stream is given below. Analyse the recession limb of the hydrograph and determine the recession coefficients. Neglect interflow.

Time (days) 0 0.5 1.0 1.5

Discharge (m3/s) 155 70.0 38.0 19.0

Time (days)

Discharge (m3/s)

Time (days)

2.0 2.5 3.0 3.5

9.0 5.5 3.5 2.5

4.0 5.0 6.0 7.0

Discharge (m3/s) 1.9 1.4 1.2 1.1

Estimate the groundwater storage at the end of 7th day from the occurrence of peak. 6.2 On June 1, 1980 the discharge in a stream was measured as 80 m3/s. Another measurement on June 21, 1980 yielded the stream discharge as 40 m3/s. There was no rainfall in the catchment from April 15, 1980. Estimate the (a) recession coefficient, (b) expected stream flow and groundwater storage available on July 10, 1980. Assume that there is no further rainfall in the catchment up to that date. 6.3 If Q(t) = Q0 Kt describes the base flow recession in a stream, prove that the storage S(t1) left in the basin at any time for supplying base flow follows the linear reservoir model, viz. S(t1) = C Q (t1), where C is a constant. [Hint: Use the boundary condition: at t = ¥, S¥ = 0 and Q¥ = 0] 6.4 A 4 -hour storm occurs over an 80 km2 watershed. The details of the catchment are as follows.

Sub Area (km2)

f-Index (mm/hour)

15 25 35 5

10 15 21 16

1st hour 16 16 12 15

Hourly Rain (mm) 2nd hour 3rd hour 48 22 42 20 40 18 42 18

4th hour 10 8 6 8

Calculate the runoff from the catchment and the hourly distribution of the effective rainfall for the whole catchment. 6.5 Given below are observed flows from a storm of 6-h duration on a stream with a catchment area of 500 km2

Time (h) 0 6 12 18 24 30 Observed flow (m3/s) 0 100 250 200 150 100

36

42

48

54

60

70

50

35

25

15

66 72 5

238 Engineering Hydrology 6.6

6.7

Assuming the base flow to be zero, derive the ordinates of the 6-h unit hydrograph. A flood hydrograph of a river draining a catchment of 189 km2 due to a 6 hour isolated storm is in the form of a triangle with a base of 66 hour and a peak ordinate of 30 m3/s occurring at 10 hours from the start. Assuming zero base flow, develop the 6-hour unit hydrograph for this catchment. The following are the ordinates of the hydrograph of flow from a catchment area of 770 km2 due to a 6-h rainfall. Derive the ordinates of the 6-h unit hydrograph. Make suitable assumptions regarding the base flow.

Time from beginning of storm (h) 0 Discharge (m3/s) 40 6.8

6

54

60

66 72

65 215 360 400 350 270 205 145 100

70

50 42

18

24

30

36

42

48

Analysis of the surface runoff records of a 1-day storm over a catchment yielded the following data:

Time (days) Discharge (m3/s) Estimated base flow (m3/s)

6.9

12

0 20

1 63

2 151

3 133

4 90

5 63

6 44

7 29

8 20

9 20

20

22

25

28

28

26

23

21

20

20

Determine the 24-h distribution graph percentages. If the catchment area is 600 km2, determine the depth of rainfall excess. The ordinates of a hydrograph of surface runoff resulting from 4.5 cm of rainfall excess of duration 8 h in a catchment are as follows:

Time (h) Discharge (m3/s)

0 0

5 40

13 210

21 400

28 600

Time (h) 61 91 Discharge (m3/s) 1190 650

98 520

115 290

138 0

32 35 41 45 55 820 1150 1440 1510 1420

Determine the ordinates of the 8-h unit hydrograph for this catchment.

6.10 The peak of a flood hydrograph due to a 6-h storm is 470 m3/s. The mean depth of rainfall is 8.0 cm. Assume an average infiltration loss of 0.25 cm/h and a constant base flow of 15 m3/s and estimate the peak discharge of the 6-h unit hydrograph for this catchment. 6.11 Given the following data about a catchment of area 100 km2, determine the volume of surface runoff and peak surface runoff discharge corresponding to a storm of 60 mm in 1 hour.

Time (h) Rainfall (mm) Runoff (m3/s)

0 0 300

1

2

3

4

5

40 0 300 1200

0 450

0 300

0 300

6.12 The ordinates of a 6-h unit hydrograph are given.

Time (h) 0 3 6 9 12 18 24 30 36 42 48 54 60 66 6-h UH ordinate (m2/s) 0 150 250 450 600 800 700 600 450 320 200 100 50 0

Hydrographs

239

A storm had three successive 6-h intervals of rainfall magnitude of 3.0, 5.0 and 4.0 cm, respectively. Assuming a f index of 0.20 cm/h and a base flow of 30 m3/s, determine and plot the resulting hydrograph of flow. 6.13 The ordinates of a 6-h unit hydrograph are as given below:

Time (h) ordinate of 6-h UH (m3/s)

6

20

12

18

24

30

36

42

48

54

60

66

60 150 120

90

66

50

32

20

10

If two storms, each of 1-cm rainfall excess and 6-h duration occur in succession, calculate the resulting hydrograph of flow. Assume base flow to be uniform at 10 m3/s. 6.14 Using the 6-h unit hydrograph of Prob. 6.13 derive a 12-h unit hydrograph for the catchment. 6.15 The ordinates of the 2-h unit hydrograph of a basin are given:

Time (h) 2-h UH ordinate (m3/s)

0 0

2

4

6

8

10

12

14

16

18

20

22

25 100 160 190 170 110

70

30

20

6

Determine the ordinates of the S2-curve hydrograph and using this S2-curve, determine the ordinates of the 4-h unit hydrograph of the basin. 6.16 The 6-hour unit hydrograph of a catchment is triangular in shape with a base width of 64 hours and a peak ordinate of 30 m3/s. Calculate the equilibrium discharge of the S6-curve of the basin. 6.17 Ordinates of the one hour unit hydrograph of a basin at one-hour intervals are 5, 8, 5, 3 and 1 m3/s. Calculate the (i) watershed area represented by this unit hydrograph. (ii) S1-curve hydrograph. (iii) 2-hour unit hydrograph for the catchment. 6.18 Using the ordinates of a 12-h unit hydrograph given below, compute the ordinates of the 6-h unit hydrograph of the basin.

Time (h) 0 6 12 18 24 30 36 42 48

Ordinate of 12-h UH (m3/s)

Time (h)

Ordinate of 12-h UH (m3/s)

Time (h)

0 10 37 76 111 136 150 153 146

54 60 66 72 78 84 90 96 106

130 114 99 84 71 58 46 35 25

108 114 120 126 132 138 144

Ordinate of 12-h UH (m3/s) 17 12 8 6 3 2 0

[Note that the tail portion of the resulting 6-h UH needs fairing.] 6.19 The 3-h unit hydrograph for a basin has the following ordinates. Using the S-curve method, determine the 9-h unit hydrograph ordinates of the basin.

240 Engineering Hydrology Time (h) 3-h UH ordinates (m3/s)

3

Time (h) 3-h UH ordinates (m3/s)

6

9

12

15

18

21

24

27

30

12

75 132 180 210 183 156 135 144

96

33

36

39

42

45

48

51

54

57

60

87

66

54

42

33

24

18

12

6

6

6.20 Using the given 6-h unit hydrograph derive the flood hydrograph due to the storm given below. UH:

Time (h)

6

6-h UH ordinates (m3/s)

20

12

18

24

30

36

42

48

54

60 66

60 150 120

90

66

50

32

20

10

Storm:

Time from beginning of the storm (h)

6

12

18

Accumulated rainfall (cm)

4

5

10

The j index for the storm can be assumed to be 0.167 cm/h. Assume the base flow to be 20 m3/s constant throughout. 6.21 The 6-hour unit hydrograph of a basin is triangular in shape with a peak of 100 m3/s occurring at 24-h from the start. The base is 72-h. (a) What is the area of the catchment represented by this unit hydrograph? (b) Calculate the flood hydrograph due to a storm of rainfall excess of 2.0 cm during the first 6 hours and 4.0 cm during the second 6 hours interval. The base flow can be assumed to be 25 m3/s constant throughout. 6.22 The 6-h unit hydrograph of a catchment of area 1000 km2 can be approximated as a triangle with base of 69 h. Calculate the peak ordinate of this unit hydrograph. 6.23 The 4-h, distribution graph of a catchment of 50 km2 area has the following ordinates:

Unit periods (4-h units) Distribution (percentage)

1 5

2 20

3 40

4 20

5 10

6 5

If the catchment has rainfalls of 3.5. 2.2 and 1.8 cm in three consecutive 4-h periods, determine the resulting direct runoff hydrograph by assuming the j-index for the storm as 0.25 cm/h. 6.24 The 6-h unit hydrograph of a catchment of area 259.2 km2 is triangular in shape with a base width of 48 hours. The peak occurs at 12 h from the start. Derive the coordinates of the 6-h distribution graph for this catchment. 6.25 The one-hour unit hydrograph of a small rural catchment is triangular in shape with a peak value of 3.6 m3/s occurring at 3 hours from the start and a base time of 9 hours. Following urbanisation over a period of two decades, the infiltration index j has decreased from 0.70 cm/h to 0.40 cm/h. Also the one-hour unit hydrograph has now a peak of 6.0 m3/s at 1.5 hours and a time base of 6 hours. If a design storm has intensities of 4.0 cm/h and 3.0 cm/h for two consecutive one hour intervals, estimate the percentage increase in the peak storm runoff and in the volume of flood runoff, due to urbanisation. 6.26 The following table gives the ordinates of a direct-runoff hydrograph resulting from two successive 3-h durations of rainfall excess values of 2 and 4 cm, respectively. Derive the 3-h unit hydrograph for the catchment.

Hydrographs

241

Time (h)

3

6

9

12

15

18

21

24

27

30

Direct runoff (m3/s)

120

480

660

460

260

160

100

50

20

6.27 Characteristics of two catchments M and N measured from a map are given below:

Item Lca L A

Catchment M 76 km 148 km 2718 km2

Catchment N 52 km 106 km 1400 km2

For the 6-h unit hydrograph in catchment M, the peak discharge is at 200 m3/s and occurs at 37 h from the start of the rainfall excess. Assuming the catchments M and N are meteorologically similar, determine the elements of the 6-h synthetic unit hydrograph for catchment N by using Snyder’s method. 6.28 A basin has an area of 400 km2, and the following characteristics: L = basin length = 35 km Lca = Length up to the centroid of the basin = 10 km Snyder’s coefficients: Ct = 1.5 and Cp = 0.70. Develop synthetically the 3-h synthetic-unit hydrograph for this basin using Snyder’s method. 6.29 Using the peak discharge and time to peak values of the unit hydrograph derived in Prob. 6.27, develop the full unit hydrograph by using the SCS dimensionless-unit hydrograph. 6.30 The rainfall excess of a storm is modelled as

I(t) = 6 cm/s

for

0 £t£4h

I(t) = 0 for t³4h The corresponding direct runoff hydrograph is expressed in terms of depth over unit catchment area per hour (cm/h) as Q(t) = 6.0 t cm/h for 0 £ t £ 4 h Q(t) = 48 – 6.0 t cm/h for 8 > t ³ 4 h Q(t) = 0 for t>8 where t is in hours. Determine the (i) 4-h unit hydrograph of the catchment and corresponding S-curve of the catchment (ii) 3-h unit hydrogen of the catchment. 6.31 A 2-h unit hydrograph is given by U(t) = 0.5 cm/h for 0 £ t £ 2 h U(t) = 0 for t³4h (i) Determine the S-curve corresponding to the given 2-h UH (ii) Using the S-curve developed above, determine the 4-h unit hydrograph 6.32 A 1-h unit hydrograph is rectangular in shape with a base of 3 hours and peak of 100 m3/ s. Develop the DRH due to an ERH given below:

Time since start (h) Excess Rainfall (cm)

1 3

2 0

3 5

6.33 A 750 ha watershed has a time of concentration of 90 minutes. (i) Derive the 15-minute unit hydrograph for this watershed by using SCS triangular unit hydrograph method. (ii) What would be the DRH for a 15-minute storm having 4.0 cm of rainfall?

242 Engineering Hydrology 6.34 The IUH of a catchment is triangular in shape with a base of 36 h and peak of 20 m3/s occurring at 8 hours from the start. Derive the 2-h unit hydrograph for this catchment. 6.35 The coordinates of the IUH of a catchment are as below:

Time (h)

1

2

3

4

5

6

8

10

12

14

16

18

20

Ordinates (m3/s) 0

11

37

60

71

75

72

60

45

33

21

12

6

(a) What is the areal extent of the catchment? (b) Derive the 3-hour unit hydrograph for this catchment.

OBJECTIVE QUESTIONS 6.1 The recession limb of a flood hydrograph can be expressed with positive values of coefficients, as Qt/Q0 = 2

6.2

6.3

6.4

6.5 6.6

6.7

6.8

– at – at (a) K cat (b) a Kt (c) a–at (d) e For a given storm, other factors remaining same, (a) basins having low drainage density give smaller peaks in flood hydrographs (b) basins with larger drainage densities give smaller flood peaks (c) low drainage density basins give shorter time bases of hydrographs (d) the flood peak is independent of the drainage density. Base-flow separation is performed (a) on a unit hydrograph to get the direct-runoff hydrograph (b) on a flood hydrograph to obtain the magnitude of effective rainfall (c) on flood hydrographs to obtain the rainfall hyetograph (d) on hydrographs of effluent streams only. A direct-runoff hydrograph due to a storm was found to be triangular in shape with a peak of 150 m3/s, time from start of effective storm to peak of 24 h and a total time base of 72 h. The duration of the storm in this case was (a) < 24 h (b) between 24 to 72 h (c) 72 h (d) > 72 h. A unit hydrograph has one unit of (a) peak discharge (b) rainfall duration (c) direct runoff (d) the time base of direct runoff. The basic assumptions of the unit-hydrograph theory are (a) nonlinear response and time invariance (b) time invariance and linear response (c) linear response and linear time variance (d) nonlinear time variance and linear response. The D-hour unit hydrograph of a catchment may be obtained by dividing the ordinates of a single peak direct runoff hydrograph (DRH) due to a storm of D hour duration by the (a) Total runoff volume (in cm) (b) Direct runoff volume (in cm) (c) Duration of DRH (d) Total rainfall (in cm) A storm hydrograph was due to 3 h of effective rainfall. It contained 6 cm of direct runoff. The ordinates of DRH of this storm (a) when divided by 3 give the ordinates of a 6-h unit hydrograph (b) when divided by 6 give the ordinates of a 3-h unit hydrograph

Hydrographs

6.9

6.10

6.11

6.12

6.13

6.14

6.15

243

(c) when divided by 3 give the ordinates of a 3-h unit hydrograph (d) when divided by 6 give the ordinates of a 6-h unit hydrograph. A 3-hour storm over a watershed had an average depth of 27 mm. The resulting flood hydrograph was found to have a peak flow of 200 m3/s and a base flow of 20 m3/s. If the loss rate could be estimated as 0.3 cm/h, a 3-h unit hydrograph for this watershed will have a peak of (b) 100 m3/s (c) 111.1 m3/s (d) 33.3 m3/s (a) 66.7 m3/s A triangular DRH due to a storm has a time base of 80 hrs and a peak flow of 50 m3/s occurring at 20 hours from the start. If the catchment area is 144 km2, the rainfall excess in the storm was (a) 20 cm (b) 7.2 cm (c) 5 cm (d) none of these. The 12-hr unit hydrograph of a catchment is triangular in shape with a base width of 144 hours and a peak discharge value of 23 m3/s. This unit hydrograph refers to a catchment of area (b) 596 km2 (c) 1000 km2 (d) none of these. (a) 756 km2 The 6-h unit hydrograph of a catchment is triangular in shape with a base width of 64 h and peak ordinate of 20 m3/s. If a 0.5 cm rainfall excess occurs in 6 h in that catchment, the resulting surface-runoff hydrograph will have (a) a base of 128 h (b) a base of 32 h (d) a peak of 10 m3/s (c) a peak of 40 m3/s A 90 km2 catchment has the 4-h unit hydrograph which can be approximated as a triangle. If the peak ordinate of this unit hydrograph is 10 m3/s the time base is (a) 120 h (b) 64 h (c) 50 h (d) none of these. A triangular DRH due to a 6-h storm in a catchment has a time base of 100 h and a peak flow of 40 m3/s. The catchment area is 180 km2. The 6-h unit hydrograph of this catchment will have a peak flow in m3/s of (a) 10 (b) 20 (c) 30 (d) none of these. The 3-hour unit hydrograph U1 of a catchment of area 250 km2 is in the form of a triangle with peak discharge of 40 m3/s. Another 3-hour unit hydrograph U2 is also triangular in shape and has the same base width as U1 but with a peak flow of 80 m3/s. The catchment which U2 refers to has an area of

(a) 125 km2 (b) 250 km2 (c) 1000 km2 (d) 500 km2 6.16 Uc is the 6-h unit hydrograph for a basin representing 1 cm of direct runoff and Um is the direct runoff hydrograph for the same basin due to a rainfall excess of 1 mm in a storm of 6 hour duration. (a) Ordinates of Um are 1/10 the corresponding ordinates of Uc (b) Base of Um is 1/10 the base of Uc (c) Ordinates of Um are 10 times the corresponding ordinates of Uc (d) Base of Um is 10 times the base of Uc 6.17 A basin with an area of 756 km2 has the 6-h unit hydrograph which could be approximated as a triangle with a base of 70 hours. The peak discharge of direct runoff hydrograph due to 5 cm of rainfall excess in 6 hours from that basin is (a) 535 m3/s (b) 60 m3/s (c) 756 m3/s (d) 300 m3/s 6.18 The peak flow of a flood hydrograph caused by isolated storm was observed to be 120 m3/s. The storm was of 6 hours duration and had a total rainfall of 7.5 cm. If the base flow and the j-index are assumed to be 30 m3/s and 0.25 cm/h respectively, the peak ordinate of the 6-h unit hydrograph of the catchment is (a) 12.0 m3/s (b) 15.0 m3/s (c) 16.0 m3/s (d) 20.0 m3/s

244 Engineering Hydrology 6.19 The peak ordinate of 4-h unit hydrograph a basin is 80 m3/s. An isolated storm of 4-hours duration in the basin was recorded to have a total rainfall of 7.0 cm. If it is assumed that the base flow and the j-index are 20 m3/s and 0.25 cm/h respectively, the peak of the flood discharge due to the storm could be estimated as (a) 580 m3/s (b) 360 m3/s (c) 480 m3/s (d) 500 m3/s 6.20 The peak flow of a flood hydrograph caused by isolated storm was observed to be 100 m3/s. The storm had a duration of 8.0 hours and the total depth of rainfall of 7.0 cm. The base flow and the j-index were estimated as 20 m3/s and 0.25 cm/h respectively. If in the above storm the total rainfall were 9.5 cm in the same duration of 8 hours, the flood peak would have been larger by (a) 35.7% (b) 40% (c) 50% (d) 20% 6.21 For a catchment with an area of 360 km2 the equilibrium discharge of the S-curve obtained by summation of 4-h unit hydrograph is (a) 250 m3/s (b) 90 m3/s (c) 278 m3/s (d) 360 m3/s 6.22 For a catchment of area A an S-curve has been derived by using the D-hour unit hydrograph which has a time base T. In this S-curve (a) the equilibrium discharge is independent of D (b) the time at which the S-curve attains its maximum value is equal to T (c) the time at which the S-curve attains its maximum value is equal to D (d) the equilibrium discharge is independent of A 6.23 An IUH is a direct runoff hydrograph of (a) of one cm magnitude due to rainfall excess of 1-h duration (b) that occurs instantaneously due to a rainfall excess of 1-h duration (c) of unit rainfall excess precipitating instantaneously over the catchment (d) occurring at any instant in long duration 6.24 An instantaneous unit hydrograph is a hydrograph of (a) unit duration and infinitely small rainfall excess (b) infinitely small duration and of unit rainfall excess (c) infinitely small duration and of unit rainfall excess of an infinitely small area (d) unit rainfall excess on infinitely small area

Chapter

7

FLOODS

7.1 INTRODUCTION A flood is an unusually high stage in a river, normally the level at which the river overflows its banks and inundates the adjoining area. The damages caused by floods in terms of loss of life, property and economic loss due to disruption of economic activity are all too well known. Thousands of crores of rupees are spent every year in flood control and flood forecasting. The hydrograph of extreme floods and stages corresponding to flood peaks provide valuable data for purposes of hydrologic design. Further, of the various characteristics of the flood hydrograph, probably the most important and widely used parameter is the flood peak. At a given location in a stream, flood peaks vary from year to year and their magnitude constitutes a hydrologic series which enable one to assign a frequency to a given flood-peak value. In the design of practically all hydraulic structures the peak flow that can be expected with an assigned frequency (say 1 in 100 years) is of primary importance to adequately proportion the structure to accommodate its effect. The design of bridges, culvert waterways and spillways for dams and estimation of scour at a hydraulic structure are some examples wherein flood-peak values are required. To estimate the magnitude of a flood peak the following alternative methods are available: 1. Rational method 2. Empirical method 3. Unit-hydrograph technique 4. Flood-frequency studies The use of a particular method depends upon (i) the desired objective, (ii) the available data, and (iii) the importance of the project. Further the rational formula is only applicable to small-size (< 50 km2) catchments and the unit-hydrograph method is normally restricted to moderate-size catchments with areas less than 5000 km2.

7.2 RATIONAL METHOD Consider a rainfall of uniform intensity and very long duration occurring over a basin. The runoff rate gradually increases from zero to a constant value as indicated in Fig. 7.1. The runoff increases as more and more flow from remote areas of the catchment reach the outlet. Designating the time taken for a drop of water from the farthest part of the catchment to reach the outlet as tc = time of concentration, it is obvious that if the rainfall continues beyond tc, the runoff will be constant and at the peak value. The peak value of the runoff is given by Qp = C A i; for t ³ tc (7.1)

"$ Engineering Hydrology

Fig. 7.1 Runoff Hydrograph due to Uniform Rainfall where C = coefficient of runoff = (runoff/rainfall), A = area of the catchment and i = intensity of rainfall. This is the basic equation of the rational method. Using the commonly used units, Eq. (7.1) is written for field application as 1 C (itc , p ) A Qp = (7.2) 3.6 3 where Qp = peak discharge (m /s) C = coefficient of runoff (itc, p ) = the mean intensity of precipitation (mm/h) for a duration equal to tc and an exceedence probability P A = drainage area in km2 The use of this method to compute Qp requires three parameters: tc, (itc,p ) and C.

Time of Concentration ( tc ) There are a number of empirical equations available for the estimation of the time of concentration. Two of these are described below. US Practice For small drainage basins, the time of concentration is assumed to be equal to the lag time of the peak flow. Thus n

æ LL ö tc = tp of Eq. (6.10) = CtL ç ca ÷ (7.3) è S ø where tc = time of concentration in hours, CtL, L, Lca, n and S have the same meaning as in Eq. (6.10) of Chapter 6. Kirpich Equation (1940) This is the popularly used formula relating the time of concentration of the length of travel and slope of the catchment as where

tc = 0.01947 L0.77 S–0.385 (7.4) tc = time of concentration (minutes) L = maximum length of travel of water (m), and S = slope of the catchment = D H/L in which DH = difference in elevation between the most remote point on the catchment and the outlet.

Floods

"%

For easy use Eq. (7.4) is sometimes written as 0.77 tc = 0.01947 K1

where

K1 =

(7.4a)

L3 DH

Rainfall Intensity ( itc, p ) The rainfall intensity corresponding to a duration tc and the desired probability of exceedence P, (i.e. return period T = 1/P) is found from the rainfall-frequency-duration relationship for the given catchment area (Chap. 2). This will usually be a relationship of the form of Eq. (2.15), viz.

KT x ( tc + a )n in which the coefficients K, a, x and n are specific to a given area. Table 2.8 (preferably in its expanded form) could be used to estimate these coefficients to a specific catchment. In USA the peak discharges for purposes of urban area drainage are calculated by using P = 0.05 to 0.1. The recommended frequencies for various types of structures used in watershed development projects in India are as below: itc, p =

Sl. No 1 2 3 4 5 6

Types of structure Storage and Diversion dams having permanent spillways Earth dams having natural spillways Stock water dams Small permanent masonry and vegetated waterways Terrace outlets and vegetated waterways Field diversions

Return Period (Years) 50–100 25–50 25 10–15 10 15

Runoff Coefficient (C ) The coefficient C represents the integrated effect of the catchment losses and hence depends upon the nature of the surface, surface slope and rainfall intensity. The effect of rainfall intensity is not considered in the available tables of values of C. Some typical values of C are indicated in Table 7.1(a & b). Equation (7.2) assumes a homogeneous catchment surface. If however, the catchment is non-homogeneous but can be divided into distinct sub areas each having a different runoff coefficient, then the runoff from each sub area is calculated separately and merged in proper time sequence. Sometimes, a non-homogeneous catchment may have component sub areas distributed in such a complex manner that distinct sub zones cannot be separated. In such cases a weighted equivalent runoff coefficient Ce as below is used. N

å Ci Ai Ce =

1

A

(7.5)

"& Engineering Hydrology Table 7.1(a) Value of the Coefficient C in Eq. (7.2) Types of area

Value of C

A. Urban area (P = 0.05 to 0.10) Lawns: Sandy-soil, flat, 2% Sandy soil, steep, 7% Heavy soil, average, 2.7% Residential areas: Single family areas Multi units, attached Industrial: Light Heavy Streets B. Agricultural Area Flat: Tight clay;cultivated woodland Sandy loam;cultivated woodland Hilly: Tight clay;cultivated woodland Sandy loam;cultivated woodland

0.05–0.10 0.15–0.20 0.18–0.22 0.30–0.50 0.60–0.75 0.50–0.80 0.60–0.90 0.70–0.95 0.50 0.40 0.20 0.10 0.70 0.60 0.40 0.30

Table 7.1(b) Values of C in Rational Formula for Watersheds with Agricultural and Forest Land Covers Sl. No

Vegetative cover and Slope (%)

1

Cultivated Land

2

Pasture Land

3

Forest Land

Sandy Loam

Soil Texture Clay and Silty Loam

Stiff Clay

0–5 5–10 10–30

0.30 0.40 0.52

0.50 0.60 0.72

0.60 0.70 0.82

0–5 5–10 10–30

0.10 0.16 0.22

0.30 0.36 0.42

0.40 0.55 0.60

0–5 5–10 10–30

0.10 0.25 0.30

0.30 0.35 0.50

0.40 0.50 0.60

where Ai = the areal extent of the sub area i having a runoff coefficient Ci and N = number of sub areas in the catchment. The rational formula is found to be suitable for peak-flow prediction in small catchments up to 50 km2 in area. It finds considerable application in urban drainage designs and in the design of small culverts and bridges.

"'

Floods

It should be noted that the word rational is rather a misnomer as the method involves the determination of parameters tc and C in a subjective manner. Detailed description and the practice followed in using the rational method in various countries are given in detail in Ref. 7. EXAMPLE 7.1(a) An urban catchment has an area of 85 ha. The slope of the catchment is 0.006 and the maximum length of travel of water is 950 m. The maximum depth of rainfall with a 25-year return period is as below: Duration (min) Depth of rainfall (mm)

5 17

10 26

20 40

30 50

40 57

60 62

If a culvert for drainage at the outlet of this area is to be designed for a return period of 25 years, estimate the required peak-flow rate, by assuming the runoff coefficient as 0.3. SOLUTION: The time of concentration is obtained by the Kirpich formula [Eq.(7.4)] as tc = 0.01947 ´ (950)0.77 ´ (0.006)–0.385 = 27.4 minutes

By interpolation, Maximum depth of rainfall for 27.4-min duration =

(50 - 40) 10

Average intensity = itc, p = By Eq. (7.2),

Qp =

´ 7.4 + 40 = 47.4 mm

47.4 ´ 60 = 103.8 mm/h 27.4

0.30 ´ 103.8 ´ 0.85 3.6

= 7.35 m3/s

EXAMPLE 7.1(b) If in the urban area of Example 7.1(a), the land use of the area and the corresponding runoff coefficients are as given below, calculate the equivalent runoff coefficient. Land use Roads Lawn Residential area Industrial area

Area (ha)

Runoff coefficient

8 17 50 10

0.70 0.10 0.30 0.80 N

SOLUTION: Equivalent runoff coefficient Ce = Ce =

å Ci Ai 1

A [(0.7 ´ 8) + (0.1 ´ 17) + (0.3 ´ 50) + (0.8 ´ 10)]

[8 + 17 + 50 + 10]

30.3 = = 0.36 85

EXAMPLE 7.2 A 500 ha watershed has the land use/cover and corresponding runoff coefficient as given below:

# Engineering Hydrology Land use/cover

Area (ha)

Forest Pasture Cultivated land

Runoff coefficient

250 50 200

0.10 0.11 0.30

The maximum length of travel of water in the watershed is about 3000 m and the elevation difference between the highest and outlet points of the watershed is 25 m. The maximum intensity duration frequency relationship of the watershed is given by 6.311T 0.1523 ( D + 0.50)0.945 water i = intensity in cm/h, T = Return period in years and D = duration of the rainfall in hours. Estimate the (i) 25 year peak runoff from the watershed and (ii) the 25 year peak runoff if the forest cover has decreased to 50 ha and the cultivated land has encroached upon the pasture and forset lands to have a total coverage of 450 ha.

i=

SOLUTION: N

Case 1: Equivalent runoff coefficient Ce = =

å Ci Ai 1

A [(0.10 ´ 250) + (0.11 ´ 50) + (0.30 ´ 200)] 500

= 0.181

By Eq. (7.4a) time of concentration tc = 0.01947 (K1)0.77 with K1 =

Since

L = 3000 m and DH = 25 m

K1 =

(3000)3 25

L3 DH = 32863

tc = 0.01947 (32863)0.77 = 58.5 min = 0.975 h Calculation of itc,p: Here D = tc = 0.975 h. T = 25 years. Hence i=

6.311(25)0.1523 (0.975 + 0.50)0.945

= 10.304/1.447 = 7.123 cm/h = 71.23 mm/h

Peak Flow by Eq. (7.2), Qp = (1/3.6)(Ce i A) 0.181 ´ 71.23 ´ (500/100) = = 64.46 m3/s 3.6 [(0.10 ´ 50) + (0.30 ´ 450)] = 0.28 Case 2: Here Equivalent C = Ce = 500 i = 71.23 mm/h and A = 500 ha = 5 (km)2 0.28 ´ 71.23 ´ 5 Qp = = 99.72 m3/s 3.6 i = 71.23 mm/h and A = 500 ha = 5 km2 0.28 ´ 71.23 ´ 5 Qp = = 99.72 m3/s 3.6

#

Floods

7.3 EMPIRICAL FORMULAE The empirical formulae used for the estimation of the flood peak are essentially regional formulae based on statistical correlation of the observed peak and important catchment properties. To simplify the form of the equation, only a few of the many parameters affecting the flood peak are used. For example, almost all formulae use the catchment area as a parameter affecting the flood peak and most of them neglect the flood frequency as a parameter. In view of these, the empirical formulae are applicable only in the region from which they were developed and when applied to other areas they can at best give approximate values.

Flood Peak-Area Relationships By far the simplest of the empirical relationships are those which relate the flood peak to the drainage area. The maximum flood discharge Qp from a catchment area A is given by these formulae as Qp = f(A) While there are a vast number of formulae of this kind proposed for various parts of the world, only a few popular formulae used in various parts of India are given below. Dickens Formula (1865) Qp = CD A3/4

(7.6) A = catchment area (km2) Qp = maximum flood discharge (m3/s) CD = Dickens constant with value between 6 to 30 The following are some guidelines in selecting the value of CD:

where

Value of CD North-Indian plains North-Indian hilly regions Central India Coastal Andhra and Orissa

6 11–14 14–28 22–28

For actual use the local experience will be of aid in the proper selection of CD. Dickens formula is used in the central and northern parts of the country. Ryves Formula (1884) Qp = CR A2/3

3

(7.7) A = catchment area (km ) 2

where Qp = maximum flood discharge (m /s) and CR = Ryves coefficient This formula originally developed for the Tamil Nadu region, is in use in Tamil Nadu and parts of Karnataka and Andhra Pradesh. The values of CR recommended by Ryves for use are: CR = 6.8 for areas within 80 km from the east coast = 8.5 for areas which are 80–160 km from the east coast = 10.2 for limited areas near hills Inglis Formula (1930) This formula is based on flood data of catchments in Western Ghats in Maharashtra. The flood peak Qp in m3/s is expressed as

#

Engineering Hydrology

Qp =

124 A A + 10.4

(7.8)

where A is the catchment area in km2. Equation (7.8) with small modifications in the constant in the numerator (124) is in use Maharashtra for designs in small catchments. Other Formulae There are many such empirical formulae developed in various parts of the world. References 3 and 5 list many such formulae suggested for use in various parts of India as well as of the world. There are some empirical formulae which relate the peak discharge to the basin area and also include the flood frequency. Fuller’s formula (1914) derived for catchments in USA is a typical one of this kind and is given by QTp = Cf A0.8 (1 + 0.8 log T) (7.9) 3 where QTp = maximum 24-h flood with a frequency of T years in m /s, A = catchment area in km2, Cf = a constant with values between 0.18 to 1.88. Envelope Curves In regions having same climatological characteristics, if the available flood data are meagre, the enveloping curve technique can be used to develop a relationship between the maximum flood flow and drainage area. In this method the available flood peak data from a large number of catchments which do not significantly differ from each other in terms of meteorological and topographical characteristics are collected. The data are then plotted on a log-log paper as flood peak vs catchment area. This would result in a plot in which the data would be scattered. If an enveloping curve that would encompass all the plotted data points is drawn, it can be used to obtain maximum peak discharges for any given area. Envelop curves thus obtained are very useful in getting quick rough estimations of peak values. If equations are fitted to these enveloping curves, they provide empirical flood formulae of the type, Q = f (A). Kanwarsain and Karpov (1967) have presented enveloping curves representing the relationship between the peak-flood flow and catchment area for Indian conditions. Two curves, one for the south Indian rivers and the other for north Indian and central Indian rivers, are developed (Fig. 7.2). These two curves are based on data covering large catchment areas, in the range 103 to 106 km2. Based on the maximum recorded floods throughout the world, Baird and McIllwraith (1951) have correlated the maximum flood discharge Qmp in m3/s with catchment area A in km2 as 3025 A (7.10) Qmp = (278 + A) 0.78 EXAMPLE 7.3 Estimate the maximum flood flow for the following catchments by using an appropriate empirical formula: 1. 2. 3. 4.

A1 = 40.5 km2 for western Ghat area, Maharashtra A2 = 40.5 km2 in Gangetic plain A3 = 40.5 km2 in the Cauvery delta, Tamil Nadu What is the peak discharge for A = 40.5 km2 by maximum world flood experience?

Floods

#!

Fig. 7.2 Enveloping Curves for Indian Rivers SOLUTION:

1. For this catchment, the Inglis formula is recommended. By the Inglis formula [Eq. (7.8)], 124 ´ 40.5 = 704 m3/s Qp = 40.5 + 10.4 2. In this case Dickens formula [Eq. (7.6)] with CD = 6.0 is recommended. Hence

Qp = 6.0 ´ (40.5)0.75 = 96.3 m3/s 3. In this case Ryves formula [Eq. (7.7)] with CR = 6.8 is preferred, and this gives Qp = 6.8 (40.5)2/3 = 80.2 m3/s 4. By Eq. (7.10) for maximum peak discharge based on world experience, 3025 ´ 40.5 Qmp = = 1367 m3/s. (278 + 40.5)0.78

7.4 UNIT HYDROGRAPH METHOD The unit hydrograph technique described in the previous chapter can be used to predict the peak-flood hydrograph if the rainfall producing the flood, infiltration characteristics of the catchment and the appropriate unit hydrograph are available. For design purposes, extreme rainfall situations are used to obtain the design storm, viz. the hydrograph of the rainfall excess causing extreme floods. The known or derived unit hydrograph of the catchment is then operated upon by the design storm to generate the desired flood hydrograph. Details about this use of unit hydrograph are given in Sec. 7.12.

7.5 FLOOD FREQUENCY STUDIES Hydrologic processes such as floods are exceedingly complex natural events. They are resultants of a number of component parameters and are therefore very difficult to model analytically. For example, the floods in a catchment depend upon the

#" Engineering Hydrology characteristics of the catchment, rainfall and antecedent conditions, each one of these factors in turn depend upon a host of constituent parameters. This makes the estimation of the flood peak a very complex problem leading to many different approaches. The empirical formulae and unit hydrograph methods presented in the previous sections are some of them. Another approach to the prediction of flood flows, and also applicable to other hydrologic processes such as rainfall etc. is the statistical method of frequency analysis. The values of the annual maximum flood from a given catchment area for large number of successive years constitute a hydrologic data series called the annual series. The data are then arranged in decreasing order of magnitude and the probability P of each event being equalled to or exceeded (plotting position) is calculated by the plotting-position formula m P= (7.11) N +1 where m = order number of the event and N = total number of events in the data. The recurrence interval, T (also called the return period or frequency) is calculated as T = 1/P (7.12) The relationship between T and the probability of occurrence of various events is the same as described in Sec. 2.11. Thus, for example, the probability of occurrence of the event r times in n successive years is given by n! Prn = nCr P r qn–r = P r qn–r ( n - r )! r ! where q=1–P Consider, for example, a list of flood magnitudes of a river arranged in descending order as shown in Table 7.2. The length of the record is 50 years. Table 7.2 Calculation of Frequency T Order No. m

Flood magnitude Q (m3/s)

T in years = 51/m

1 2 3 4 : : : 49 50

160 135 128 116 : : : 65 63

51.00 25.50 17.00 12.75 : : : 1.04 1.02

The last column shows the return period T of various flood magnitude, Q. A plot of Q vs T yields the probability distribution. For small return periods (i.e. for interpolation) or where limited extrapolation is required, a simple best-fitting curve through plotted points can be used as the probability distribution. A logarithmic scale for T is often advantageous. However, when larger extrapolations of T are involved, theoretical probability distributions have to be used. In frequency analysis of floods the usual

##

Floods

problem is to predict extreme flood events. Towards this, specific extreme-value distributions are assumed and the required statistical parameters calculated from the available data. Using these the flood magnitude for a specific return period is estimated. Chow (1951) has shown that most frequency distribution functions applicable in hydrologic studies can be expressed by the following equation known as the general equation of hydrologic frequency analysis: xT = x + Ks (7.13) where xT = value of the variate X of a random hydrologic series with a return period T, x = mean of the variate, s = standard deviation of the variate, K = frequency factor which depends upon the return period, T and the assumed frequency distribution. Some of the commonly used frequency distribution functions for the predication of extreme flood values are 1. Gumbel’s extreme-value distribution, 2. Log-Pearson Type III distribution 3. Log normal distribution. Only the first two distributions are dealt with in this book with emphasis on application. Further details and theoretical basis of these and other methods are available in Refs. 2, 3, 7 and 8.

7.6 GUMBEL’S METHOD This extreme value distribution was introduced by Gumbel (1941) and is commonly known as Gumbel’s distribution. It is one of the most widely used probability distribution functions for extreme values in hydrologic and meteorologic studies for prediction of flood peaks, maximum rainfalls, maximum wind speed, etc. Gumbel defined a flood as the largest of the 365 daily flows and the annual series of flood flows constitute a series of largest values of flows. According to his theory of extreme events, the probability of occurrence of an event equal to or larger than a value x0 is –y

–e P (X ³ x0) = 1 – e in which y is a dimensionless variable given by y = a (x – a) a = x – 0.45005 sx

(7.14) a = 1.2825/sx

1.285( x - x ) + 0.577 (7.15) sx where x = mean and sx = standard deviation of the variate X. In practice it is the value of X for a given P that is required and as such Eq. (7.14) is transposed as yp = –ln [–ln (1 – P)] (7.16) Noting that the return period T = 1/P and designating yT = the value of y, commonly called the reduced variate, for a given T Thus

or

y=

é T ù yT = - êln. ln T - 1 úû ë é T ù yT = - ê0.834 + 2.303 log log T - 1 úû ë

(7.17) (7.17a)

#$ Engineering Hydrology Now rearranging Eq. (7.15), the value of the variate X with a return period T is xT = x + K sx (7.18)

( yT - 0.577)

(7.19) 1.2825 Note that Eq. (7.18) is of the same form as the general equation of hydrologic-frequency analysis (Eq. (7.13)). Further, Eqs. (7.18) and (7.19) constitute the basic Gumbel’s equations and are applicable to an infinite sample size (i.e. N ® ¥). Since practical annual data series of extreme events such as floods, maximum rainfall depths, etc., all have finite lengths of record (Eq. (7.19)) is modified to account for finite N as given below for practical use. where

K=

Gumbel’s Equation for Practical Use Equation (7.18) giving the value of the variate X with a recurrence interval T is used as xT = x + K sn–1 (7.20) where

in which

sn–1 = standard deviation of the sample of size N = K = frequency factor expressed as yT - yn K= Sn yT = reduced variate, a function of T and is given by

S ( x - x )2 N -1

(7.21)

é T ù yT = - êln. ln (7.22) T - 1 úû ë é T ù or yT = - ê0.834 + 2.303 log log T - 1 úû ë yn = reduced mean, a function of sample size N and is given in Table 7.3; for N ® ¥, yn ® 0.577 Sn = reduced standard deviation, a function of sample size N and is given in Table 7.4; for N ® ¥, Sn ® 1.2825 These equations are used under the following procedure to estimate the flood magnitude corresponding to a given return based on an annual flood series. 1. Assemble the discharge data and note the sample size N. Here the annual flood value is the variate X. Find x and sn – 1 for the given data. 2. Using Tables 7.3 and 7.4 determine yn and Sn appropriate to given N. 3. Find yT for a given T by Eq. (7.22). 4. Find K by Eq. (7.21). 5. Determine the required xT by Eq. (7.20). The method is illustrated in Example 7.3. To verify whether the given data follow the assumed Gumbel’s distribution, the following procedure may be adopted. The value of xT for some return periods T < N are calculated by using Gumbel’s formula and plotted as xT vs T on a convenient paper such as a semi-log, log-log or Gumbel probability paper. The use of Gumbel probability paper results in a straight line for xT vs T plot. Gumbel’s distribution has the property

0.4952 0.5236 0.5362 0.5436 0.5485 0.5521 0.5548 0.5569 0.5586 0.5600

10 20 30 40 50 60 70 80 90 100

0.9496 1.0628 1.1124 1.1413 1.1607 1.1747 1.1854 1.1938 1.2007 1.2065

N

10 20 30 40 50 60 70 80 90 100

N = sample size

N

N = sample size 0.5035 0.5268 0.5380 0.5448 0.5493 0.5527 0.5552 0.5572 0.5589

2 0.5070 0.5283 0.5388 0.5453 0.5497 0.5530 0.5555 0.5574 0.5591

3 0.5100 0.5296 0.5396 0.5458 0.5501 0.5533 0.5557 0.5576 0.5592

4 0.5128 0.5309 0.5402 0.5463 0.5504 0.5535 0.5559 0.5578 0.5593

5 0.5157 0.5320 0.5410 0.5468 0.5508 0.5538 0.5561 0.5580 0.5595

6 0.5181 0.5332 0.5418 0.5473 0.5511 0.5540 0.5563 0.5581 0.5596

7

0.9676 1.0696 1.1159 1.1436 1.1623 1.1759 1.1863 1.1945 1.2013

1 0.9833 1.0754 1.1193 1.1458 1.1638 1.1770 1.1873 1.1953 1.2020

2 0.9971 1.0811 1.1226 1.1480 1.1658 1.1782 1.1881 1.1959 1.2026

3 1.0095 1.0864 1.1255 1.1499 1.1667 1.1793 1.1890 1.1967 1.2032

4

1.0206 1.0915 1.1285 1.1519 1.1681 1.1803 1.1898 1.1973 1.2038

5

1.0316 1.0961 1.1313 1.1538 1.1696 1.1814 1.1906 1.1980 1.2044

6

1.0411 1.1004 1.1339 1.1557 1.1708 1.1824 1.1915 1.1987 1.2049

7

Table 7.4 Reduced Standard Deviation Sn in Gumbel’s Extreme Value Distribution

0.4996 0.5252 0.5371 0.5442 0.5489 0.5524 0.5550 0.5570 0.5587

1

Table 7.3 Reduced mean y n in Gumbel’s Extreme Value Distribution

1.0493 1.1047 1.1363 1.1574 1.1721 1.1834 1.1923 1.1994 1.2055

8

0.5202 0.5343 0.5424 0.5477 0.5515 0.5543 0.5565 0.5583 0.5598

8

1.0565 1.1086 1.1388 1.1590 1.1734 1.1844 1.1930 1.2001 1.2060

9

0.5220 0.5353 0.5430 0.5481 0.5518 0.5545 0.5567 0.5585 0.5599

9

Floods

#%

#& Engineering Hydrology which gives T = 2.33 years for the average of the annual series when N is very large. Thus the value of a flood with T = 2.33 years is called the mean annual flood. In graphical plots this gives a mandatory point through which the line showing variation of xT with T must pass. For the given data, values of return periods (plotting positions) for various recorded values, x of the variate are obtained by the relation T = (N + 1)/m and plotted on the graph described above. Figure 7.3 shows a good fit of observed data with the theoretical variation line indicating the applicability of Gumbel’s distribution to the given data series. By extrapolation of the straight line xT vs T, values of xT for T > N can be determined easily (Example 7.3).

Gumbel Probability Paper The Gumbel probability paper is an aid for convenient graphical representation of Gumbel’s distribution. It consists of an abscissa specially marked for various convenient values of the return period T. To construct the T scale on the abscissa, first construct an arithmetic scale of yT values, say from –2 to +7, as in Fig. 7.3. For selected values of T, say 2, 10, 50, 100, 500 and 1000, find the values of yT by Eq. (7.22) and mark off those positions on the abscissa. The T-scale is now ready for use as shown in Fig. 7.3.

Fig. 7.3 Flood probability analysis by Gumbel’s Distribution The ordinate of a Gumbel paper on which the value of the variate, xT (flood discharge, maximum rainfall depth, etc.) are plotted may have either an arithmetic scale or logarithmic scale. Since by Eqs (7.18) and (7.19) xT varies linearly with yT, a Gumbel distribution will plot as a straight line on a Gumbel probability paper. This property can be used advantageously for graphical extrapolation, wherever necessary.

#'

Floods

EXAMPLE 7.4 Annual maximum recorded floods in the river Bhima at Deorgaon, a tributary of the river Krishna, for the period 1951 to 1977 is given below. Verify whether the Gumbel extreme-value distribution fit the recorded values. Estimate the flood discharge with recurrence interval of (i) 100 years and (ii) 150 years by graphical extrapolation. Year 1951 Max. flood (m3/s) 2947

1952 1953 1954 3521 2399 4124

1955 3496

1956 2947

1957 1958 5060 4903

1959 3757

Year 1960 Max. flood (m3/s) 4798

1961 1962 1963 4290 4652 5050

1964 6900

1965 4366

1966 1967 3380 7826

1968 3320

Year 1969 Max. flood (m3/s) 6599

1970 1971 1972 3700 4175 2988

1973 2709

1974 3873

1975 1976 4593 6761

1977 1971

SOLUTION: The flood discharge values are arranged in descending order and the plotting position recurrence interval Tp for each discharge is obtained as N + 1 28 Tp = = m m where m = order number. The discharge magnitude Q are plotted against the corresponding Tp on a Gumbel extreme probability paper (Fig. 7.3). The statistics x and an sn–1 for the series are next calculated and are shown in Table 7.5. Using these the discharge xT for some chosen recurrence interval is calculated by using Gumbel’s formulae [Eqs. (7.22), (7.21) and (7.20)]. Table 7.5 Calculation of Tp for Observed Data—Example 7.4 Order number m 1 2 3 4 5 6 7 8 9 10 11 12 13 14

Flood discharge x (m3/s)

Tp (years)

Order number m

Flood discharge x (m3/s)

Tp (years)

7826 6900 6761 6599 5060 5050 4903 4798 4652 4593 4366 4290 4175 4124

28.00 14.00 9.33 7.00 5.60 4.67 4.00 3.50 3.11 2.80 2.55 2.33 2.15 2.00

15 16 17 18 19 20 21 22 23 24 25 26 27

3873 3757 3700 3521 3496 3380 3320 2988 2947 2947 2709 2399 1971

1.87 1.75 1.65 1.56 1.47 1.40 1.33 1.27 — 1.17 1.12 1.08 1.04

N = 27 years, x = 4263 m3/s, sn–1 = 1432.6 m3/s From Tables 7.3 and 7.4, for N = 27, yn = 0.5332 and Sn = 1.1004. Choosing T = 10 years, by Eq. (7.22), y T = –[ln ´ ln (10/9)] = 2.25037

$ Engineering Hydrology K=

2.25307 - 0.5332

= 1.56 1.1004 x T = 4263 + (1.56 ´ 1432.6) = 6499 m3/s Similarly, values of xT are calculated for two more T values as shown below. T years

xT [obtained by Eq. (7.20)] (m3/s)

5.0 10.0 20.0

5522 6499 7436

These values are shown in Fig. 7.3. It is seen that due to the property of the Gumbel’s extreme probability paper these points lie on a straight line. A straight line is drawn through these points. It is seen that the observed data fit well with the theoretical Gumbel’s extreme-value distribution. [Note: In view of the linear relationship of the theoretical xT and T on a Gumbel probability paper it is enough if only two values of T and the corresponding xT are calculated. However, if Gumbel’s probability paper is not available, a semi-log plot with log scale for T will have to be used and a large set of (xT, T) values are needed to identify the theoretical curve.] By extrapolation of the theoretical xT vs T relationship, from Fig. 7.3, At T = 100 years, xT = 9600 m3/s At T = 150 years, xT = 10,700 m3/s 3 [By using Eqs (7.20) to (7.22), x100 = 9558 m /s and x150 = 10,088 m3/s.]

EXAMPLE 7.5 Flood-frequency computations for the river Chambal at Gandhisagar dam, by using Gumbel’s method, yielded the following results: Return period T (years)

Peak flood (m3/s)

50 100

40,809 46,300

Estimate the flood magnitude in this river with a return period of 500 years.

SOLUTION: By Eq. (7.20), x100 = x + K100 sn–1 But

x50 = x + K50 sn–1

(K100 – K50)sn–1 = x100 – x50 = 46300 – 40809 = 5491 yn yT KT = Sn Sn

where Sn and yn are constants for the given data series. s n -1 = 5491 \ (y100 – y50) Sn By Eq. (7.22) y 100 = –[ln ´ ln (100/99)] = 4.60015 y 50 = –[ln ´ ln (50/99)] = 3.90194 s n -1 5491 = = 7864 (4.60015 - 3.90194) Sn

Floods

$

For T = 500 years, by Eq. (7.22), y 500 = – [ln ´ ln (500/499)] = 6.21361 s n -1 (y500 – y100) = x500 – x100 Sn (6.21361 – 4.60015) ´ 7864 = x500 – 46300 x500 = 58988, say 59,000 m3/s

EXAMPLE 7.6 The mean annual flood of a river is 600 m3/s and the standard deviation

of the annual flood time series is 150 m3/s. What is the probability of a flood of magnitude 1000 m3/s occurring in the river within next 5 years? Use Gumbel’s method and assume the sample size to be very large.

SOLUTION:

Hence Also, \

x = 600 m3/s and sn–1 = 150 m3/s

1000 = 600 + K(150) yT - 0.577 K = 2.6667 = 1.2825 yT = 3.9970 é T ù yT = 3.9970 = - êln × ln ú T - 1û ë T = 1.01854 T -1 T = 54.9 years, say 55 years

xT = x + Ksn–1

Probability of occurrence of a flood of magnitude 1000 m3/s = p = 1/55 = 0.0182 The probability of a flood of magnitude 1000 m3/s occurring at least once in 5 years = p1 = 1 – (1 – p)5 = 1 – (0.9818)5 = 0.0877 = 11.4%

Confidence Limits Since the value of the variate for a given return period, xT determined by Gumbel’s method can have errors due to the limited sample data used, an estimate of the confidence limits of the estimate is desirable. The confidence interval indicates the limits about the calculated value between which the true value can be said to lie with a specific probability based on sampling errors only. For a confidence probability c, the confidence interval of the variate xT is bounded by values x1 and x2 given by6 x1/2 = xT ± f(c) Se (7.23) where f(c) = function of the confidence probability c determined by using the table of normal variates as c in per cent f(c)

50 0.674

68 1.00

Se = probable error = b

80 1.282

90 1.645

s n -1 N

b = 1 + 1.3 K + 1.1 K 2 K = frequency factor given by Eq. (7.21)

95 1.96

99 2.58

(7.23a)

$

Engineering Hydrology

sn – 1 = standard deviation of the sample N = sample size. It is seen that for a given sample and T, 80% confidence limits are twice as large as the 50% limits and 95% limits are thrice as large as 50% limits. EXAMPLE 7.7 Data covering a period of 92 years for the river Ganga at Raiwala yielded the mean and standard derivation of the annual flood series as 6437 and 2951 m3/s respectively. Using Gumbel’s method estimate the flood discharge with a return period of 500 years. What are the (a) 95% and (b) 80% confidence limits for this estimate. SOLUTION: From Table 7.3 for N = 92 years, yn = 0.5589 and Sn = 1.2020 from Table 7.4. Y 500 = – [ln ´ ln (500/499)] = 6.21361 6.21361 - 0.5589 K500 = = 4.7044 1.2020 x500 = 6437 + 4.7044 ´ 2951 = 20320 m3/s From Eq. (7.33a) b=

1 + 1.3(4.7044) + 1.1(4.7044)2 = 5.61

Se = probable error = 5.61 ´

2951

= 1726 92 (a) For 95% confidence probability f(c) = 1.96 and by Eq. (7.23) x1/2 = 20320 ± (1.96 ´ 1726) x1 = 23703 m3/s and x2 = 16937 m3/s Thus estimated discharge of 20320 m3/s has a 95% probability of lying between 23700 and 16940 m3/s (b) For 80% confidence probability, f(c) = 1.282 and by Eq. (7.23) x1/2 = 20320 ± (1.282 ´ 1726) x1 = 22533 m3/s and x2 = 18107 m3/s The estimated discharge of 20320 m3/s has a 80% probability of lying between 22530 and 18110 m3/s. For the data of Example 7.7, the values of xT for different values of T are calculated and shown plotted on a Gumbel probability paper in Fig. 7.4. This variation is marked as “fitted line” in the figure. Also shown in this plot are the 95 and 80% confidence limits for various values of T. It is seen that as the confidence probability increases, the confidence interval also increases. Further, an increase in the return period T causes the confidence band to spread. Theoretical work by Alexeev (1961) has shown that for Gumbel’s distribution the coefficient of skew Cs ® 1.14 for very low values of N. Thus the Gumbel’s distribution will give erroneous results if the Fig. 7.4 Confidence Bands for sample has a value of Cs very much different Gumbels Distribution— from 1.14. Example 7.7

$!

Floods

7.7 LOG-PEARSON TYPE III DISTRIBUTION This distribution is extensively used in USA for projects sponsored by the US Government. In this the variate is first transformed into logarithmic form (base 10) and the transformed data is then analysed. If X is the variate of a random hydrologic series, then the series of Z variates where z = log x (7.24) are first obtained. For this Z series, for any recurrence interval T, Eq. (7.13) gives zT = z + Kz sz (7.25) where Kz = a frequency factor which is a function of recurrence interval T and the coefficient of skew Cs, sz = standard deviation of the Z variate sample = S ( z - z )2 /( N - 1) Cs = coefficient of skew of variate Z

and

=

N S ( z - z )3 ( N - 1) ( N - 2) (s z )3

(7.25a) (7.25b)

z = mean of the z values N = sample size = number of years of record The variations of Kz = f(Cs, T ) is given in Table 7.6. After finding zT by Eq. (7.25), the corresponding value of xT is obtained by Eq. (7.24) as xT = antilog (zT) (7.26) Sometimes, the coefficient of skew Cs, is adjusted to account for the size of the sample by using the following relation proposed by Hazen (1930). æ 1 + 8.5 ö Cˆ s = Cs ç (7.27) è N ÷ø where Cˆ s = adjusted coefficient of skew. However, the standard procedure for use of log-Pearson Type III distribution adopted by U.S. Water Resources Council does not include this adjustment for skew. When the skew is zero, i.e. Cs = 0, the log-Pearson Type III distribution reduces to log normal distribution. The log-normal distribution plots as a straight line on logarithmic probability paper.

Table 7.6 Kz = F(Cs, T ) for Use in Log-Pearson Type III Distribution Coefficient of skew, Cs 3.0 2.5 2.2 2.0 1.8 1.6 1.4

2 –0.396 –0.360 –0.330 –0.307 –0.282 –0.254 –0.225

Recurrence interval T in years 10 25 50 100 200 1.180 2.278 3.152 4.051 4.970 1.250 2.262 3.048 3.845 4.652 1.284 2.240 2.970 3.705 4.444 1.302 2.219 2.912 3.605 4.298 1.318 2.193 2.848 3.499 4.147 1.329 2.163 2.780 3.388 3.990 1.337 2.128 2.706 3.271 3.828

1000 7.250 6.600 6.200 5.910 5.660 5.390 5.110 (Contd.)

$" Engineering Hydrology (Contd.) 1.2 1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.0 –0.1 –0.2 –0.3 –0.4 –0.5 –0.6 –0.7 –0.8 –0.9 –1.0 –1.4 –1.8 –2.2 –3.0

–0.195 –0.164 –0.148 –0.132 –0.116 –0.099 –0.083 –0.066 –0.050 –0.033 –0.017 0.000 0.017 0.033 0.050 0.066 0.083 0.099 0.116 0.132 0.148 0.164 0.225 0.282 0.330 0.396

1.340 1.340 1.339 1.336 1.333 1.328 1.323 1.317 1.309 1.301 1.292 1.282 1.270 1.258 1.245 1.231 1.216 1.200 1.183 1.166 1.147 1.128 1.041 0.945 0.844 0.660

2.087 2.043 2.018 1.998 1.967 1.939 1.910 1.880 1.849 1.818 1.785 1.751 1.716 1.680 1.643 1.606 1.567 1.528 1.488 1.448 1.407 1.366 1.198 1.035 0.888 0.666

2.626 2.542 2.498 2.453 2.407 2.359 2.311 2.261 2.211 2.159 2.107 2.054 2.000 1.945 1.890 1.834 1.777 1.720 1.663 1.606 1.549 1.492 1.270 1.069 0.900 0.666

3.149 3.022 2.957 2.891 2.824 2.755 2.686 2.615 2.544 2.472 2.400 2.326 2.252 2.178 2.104 2.029 1.955 1.880 1.806 1.733 1.660 1.588 1.318 1.087 0.905 0.667

3.661 3.489 3.401 3.312 3.223 3.132 3.041 2.949 2.856 2.763 2.670 2.576 2.482 2.388 2.294 2.201 2.108 2.016 1.926 1.837 1.749 1.664 1.351 1.097 0.907 0.667

4.820 4.540 4.395 4.250 4.105 3.960 3.815 3.670 3.525 3.380 3.235 3.090 2.950 2.810 2.675 2.540 2.400 2.275 2.150 2.035 1.910 1.880 1.465 1.130 0.910 0.668

[Note: Cs = 0 corresponds to log-normal distribution]

EXAMPLE 7.8 For the annual flood series data given in Example 7.4, estimate the flood discharge for a return period of (a) 100 years (b) 200 years and (c) 1000 years by using log-Pearson Type III distribution. SOLUTION: The variate z = log x is first calculated for all the discharges (Table 7.7). Then the statistics Z , sz and Cs are calculated from Table 7.7 to obtain Table 7.7 Variate Z—Example 7.8 Year

Flood x (m3/s)

z = log x

Year

Flood x (m3/s)

z = log x

1951 1952 1953 1954 1955 1956

2947 3521 2399 4124 3496 2947

3.4694 3.5467 3.3800 3.6153 3.5436 3.4694

1965 1966 1967 1968 1969 1970

4366 3380 7826 3320 6599 3700

3.6401 3.5289 3.8935 3.5211 3.8195 3.5682 (Contd.)

Floods

(Contd.) 1957 1958 1959 1960 1961 1962 1963 1964

5060 4903 3751 4798 4290 4652 5050 6900

3.7042 3.6905 3.5748 3.6811 3.6325 3.6676 3.7033 3.8388

1971 1972 1973 1974 1975 1976 1977

4175 2988 2709 3873 4593 6761 1971

$#

3.6207 3.4754 3.4328 3.5880 3.6621 3.8300 3.2947

27 ´ 0.0030

sz = 0.1427

Cs =

Z = 3.6071

Cs = 0.043

(26) (25) (0.1427)3

The flood discharge for a given T is calculated as below. Here, values of Kz for given T and Cs = 0.043 are read from Table 7.6.

T (years) 100 200 1000

Z = 3.6071 Kz (from Table 7.6)

sz = 0.1427

Cs = 0.043

(for Cs = 0.043)

Kz s z

ZT = Z + Kzsz

(m3/s)

2.358 2.616 3.152

0.3365 0.3733 0.4498

3.9436 3.9804 4.0569

8782 9559 11400

xT = antilog zT

EXAMPLE 7.9 For the annual flood series data analyzed in Example 7.8 estimate the flood discharge for a return period of (a) 100 years, (b) 200 years, and (c) 1000 years by using log-normal distribution. Compare the results with those of Example 7.8. SOLUTION: Log-normal distribution is a special case of log-Pearson type III distribution with Cs = 0. Thus in this case Cs is taken as zero. The other statistics are z = 3.6071 and sz = 0.1427 as calculated in Example 7.8. The value of K for a given return period T and Cs = 0 is read from Table 7.6. The estimation of the required flood discharge is done as shown below. T (years)

z = 3.6071 Kz

sz = 0.1427 Kz sz

(from Table 7.6) 100 200 1000

2.326 2.576 3.090

Cs = 0 ZT = Z + Kz sz

0.3319 0.3676 0.4409

3.9390 3.9747 4.0480

xT = antilog zT (m3/s) 8690 9434 11170

On comparing the estimated xT with the corresponding values in Example 7.8, it is seen that the inclusion of the positive coefficient of skew (Cs = 0.047) in log-Pearson type III method gives higher values than those obtained by the log-normal distribution method. However, as the value of Cs is small, the difference in the corresponding values of xT by the two methods is not appreciable. [Note: If the coefficient of skew is negative, the log-Pearson type III method gives consistently lower values than those obtained by the log-normal distribution method.]

$$ Engineering Hydrology

7.8 PARTIAL DURATION SERIES In the annual hydrologic data series of floods, only one maximum value of flood per year is selected as the data point. It is likely that in some catchments there are more than one independent floods in a year and many of these may be of appreciably high magnitude. To enable all the large flood peaks to be considered for analysis, a flood magnitude larger than an arbitrary selected base value are included in the analysis. Such a data series is called partial-duration series. In using the partial-duration series, it is necessary to establish that all events considered are independent. Hence the partial-duration series is adopted mostly for rainfall analysis where the conditions of independency of events are easy to establish. Its use in flood studies is rather rare. The recurrence interval of an event obtained by annual series (TA ) and by the partial duration series (Tp ) are related by 1 TP = (7.28) ln TA - ln (TA - 1) From this it can be seen that the difference between TA and TP is significant for TA < 10 years and that for TA > 20, the difference is negligibly small.

7.9 REGIONAL FLOOD FREQUENCY ANALYSIS When the available data at a catchment is too short to conduct frequency analysis, a regional analysis is adopted. In this a hydrologically homogeneous region from the statistical point of view is considered. Available long time data from neighbouring catchments are tested for homogeneity and a group of stations satisfying the test are identified. This group of stations constitutes a region and all the station data of this region are pooled and analysed as a group to find the frequency characteristics of the region. The mean annual flood Qma, which corres-ponds to a recurrence interval of 2.33 years is used for nondimensionalising the results. The variation of Qma with drainage area and the variation of QT/Qma with T where QT is the discharge for any T are the basic plots prepared in this analysis. Details of the method are available in Ref. 2.

7.10 DATA FOR FREQUENCY STUDIES The flood-frequency analysis described in the previous sections is a direct means of estimating the desired flood based upon the available flood flow data of the catchment. The results of the frequency analysis depend upon the length of data. The minimum number of years of record required to obtain satisfactory estimates depends upon the variability of data and hence on the physical and climatological characteristics of the basin. Generally a minimum of 30 years of data is considered as essential. Smaller lengths of records are also used when it is unavoidable. However, frequency analysis should not be adopted if the length of records is less than 10 years. In the frequency analysis of time series, such as of annual floods, annual yields and of precipitation, some times one comes across very long (say of the order of 100 years) times series. In such cases it is necessary to test the series for Homogeneity to ascertain that there is no significant difference in the causative hydrological processes over the span of the time series. A time series is called time-homogeneous (also known as stationary) if identical events under consideration in the series are likely to occur at all times. Departure from time homogeneity is reflected either in trend or periodicity

Floods

%$or persistence of the variable over time. Potential non-homogeneity region, (if any), could be detected by (i) mass curve or (ii) by moving mean of the variable. Statistical tests like F-test for equality of variances and t-test for significance of differences of means are adopted to identify non- homogeneous region/s in the series. Only the contiguous homogeneous region of the series covering the recent past is to be adopted for frequency analysis. However, it is prudent to test all time series, whether long or short, for time-homogeneity before proceeding with the frequency analysis. Thus the cardinal rule with the data of time series would be that the data should be reliable and homogeneous. Flood frequency studies are most reliable in climates that are uniform from year to year. In such cases a relatively short record gives a reliable picture of the frequency distribution.

7.11 DESIGN FLOOD In the design of hydraulic structures it is not practical from economic considerations to provide for the safety of the structure and the system at the maximum possible flood in the catchment. Small structures such as culverts and storm drainages can be designed for less severe floods as the consequences of a higher than design flood may not be very serious. It can cause temporary inconvenience like the disruption of traffic and very rarely severe property damage and loss of life. On the other hand, storage structures such as dams demand greater attention to the magnitude of floods used in the design. The failure of these structures causes large loss of life and great property damage on the downstream of the structure. From this it is apparent that the type, importance of the structure and economic development of the surrounding area dictate the design criteria for choosing the flood magnitude. This section highlights the procedures adopted in selecting the flood magnitude for the design of some hydraulic structures. The following definitions are first noted.

Design Flood Flood adopted for the design of a structure. Spillway Design Flood Design flood used for the specific purpose of de-

signing the spillway of a storage structure. This term is frequently used to denote the maximum discharge that can be passed in a hydraulic structure without any damage or serious threat to the stability of the structure.

Standard Project Flood (SPF) The flood that would result from a se-

vere combination of meteorological and hydrological factors that are reasonably applicable to the region. Extremely rare combinations of factors are excluded.

Probable Maximum Flood (PMF) The extreme flood that is physically

possible in a region as a result of severemost combinations, including rare combinations of meteorological and hydrological factors. The PMF is used in situations where the failure of the structure would result in loss of life and catastrophic damage and as such complete security from potential floods is sought. On the other hand, SPF is often used where the failure of a structure would cause less severe damages. Typically, the SPF is about 40 to 60% of the PMF for the same drainage basin. The criteria used for selecting the design flood for various

$& Engineering Hydrology Table 7.8 Guidelines for Selecting Design Floods (CWC, India)1 S. No.

Structure

Recommended design flood

1.

Spillways for major and medium projects with storages more than 60 Mm3

2.

Permanent barrage and minor dams with capacity less than 60 Mm3

3.

Pickup weirs

4.

Flood with T = 50 years Aqueducts Flood with T = 100 years (a) Waterway (b) Foundations and free board Empirical formulae Project with very scanty or inadequate data

5.

(a) PMF determined by unit hydrograph and probable maximum precipitation (PMP) (b) If (a) is not applicable or possible floodfrequency method with T = 1000 years (a) SPF determined by unit hydrograph and standard project storm (SPS) which is usually the largest recorded storm in the region (b) Flood with a return period of 100 years. (a) or (b) whichever gives higher value. Flood with a return period of 100 or 50 years depending on the importance of the project.

hydraulic structures vary from one country to another. Table 7.8 gives a brief summary of the guidelines adopted by CWC India, to select design floods.

The Indian Standard Guidelines for Design of Floods for Dams “IS : 11223—1985 : Guidelines for fixing spillway capacity” (Ref. 4) is currently used in India for selection of design floods for dams. In these guidelines, dams are classified according to size by using the hydraulic head and the gross storage behind the dam. The hydraulic head is defined as the difference between the maximum water level on the upstream and the normal annual average flood level on the downstream. The classification is shown in Table 7.9(a). The overall size classifications for dams would be greater of that indicated by either of the two parameters. For example, a dam with a gross storage of 5 Mm3 and hydraulic head of 15 m would be classified as Intermediate size dam. Table 7.9(a) Size Classification of Dams Class Small Intermediate Large

Gross storage (Mm3)

Hydraulic head (m)

0.5 to 10.0 10.0 to 60.0 > 60.0

7.5 to 12.0 12.0 to 30.0 > 30.0

Floods

$'

The inflow design flood (IDF) for safety of the dam is taken for each class of dam as given in Table 7.9(b). Table 7.9(b) Inflow Design Flood for Dams Size/Class (based on Table 7.9(a))

Inflow design flood for safety

Small Intermediate Large

100-year flood Standard project flood (SPF) Probable Maximum flood (PMF)

7.12 DESIGN STORM To estimate the design flood for a project by the use of a unit hydrograph, one needs the design storm. This can be the storm-producing probable maximum precipitation (PMP) for deriving PMF or a standard project storm (SPS) for SPF calculations. The computations are performed by experienced hydrometeorologists by using meteorological data. Various methods ranging from highly sophisticated hydrometeorological methods to simple analysis of past rainfall data are in use depending on the availability of reliable relevant data and expertise. The following is a brief outline of a procedure followed in India: l The duration of the critical rainfall is first selected. This will be the basin lag if the flood peak is of interest. If the flood volume is of prime interest, the duration of the longest storm experienced in the basin is selected. l Past major storms in the region which conceivably could have occurred in the basin under study are selected. DAD analysis is performed and the enveloping curve representing maximum depth–duration relation for the study basin obtained. l Rainfall depths for convenient time intervals (e.g. 6 h) are scaled from the enveloping curve. These increments are to be arranged to get a critical sequence which produces the maximum flood peak when applied to the relevant unit hydrograph of the basin. The critical sequence of rainfall increments can be obtained by trial and error. Alternatively, increments of precipitation are first arranged in a table of relevant unit hydrograph ordinates, such that (i) the maximum rainfall increment is against the maximum unit hydrograph ordinate, (ii) the second highest rainfall increment is against the second largest unit hydrograph ordinate, and so on, and (iii) the sequence of rainfall increments arranged above is now reversed, with the last item first and first item last. The new sequence gives the design storm (Example 7.8). l The design storm is then combined with hydrologic abstractions most conducive to high runoff, viz. low initial loss and lowest infiltration rate to get the hyetograph of rainfall excess to operate upon the unit hydrograph. Further details about the above procedure and other methods for computing design storms are available in Ref. 7. Reference 1 gives details of the estimation of the design flood peak by unit hydrographs for small drainage basins of areas from 25–500 km2. EXAMPLE 7.10 The ordinates of cumulative rainfall from the enveloping maximum depth–duration curve for a basin are given below. Also given are the ordinates of a 6-h unit hydrograph. Design the critical sequence of rainfall excesses by taking the j index to be 0.15 cm/h.

% Engineering Hydrology SOLUTION: The critical storm and rainfall excesses are calculated in a tabular form in Table 7.10.

Time from start (h) Cumulative rainfall (cm) 6-h UH ordinate (m3/s)

12

18

24

30

36

42

15 24.1

30

34

37

39

40.5 41.3

20

54

98

126

146

154

152

72

78

84

90

96

102

79

64

52

40

30

20

Time from start (h) 66 6-h UH ordinate (m3/s) 92

6

48

54

60

138

122

106

108

114

129

132

14

10

6

Table 7.10 Calculation of Critical Storm—Example 7.10 Time Cumulative 6-h Ordinate First Design Infiltra- Rainfall (h) rainfall increof 6-h arrange- sequence tion excess of (cm) mental UH ment of of rainfall loss (cm) design rainfall (m3/s) rainfall increstorm (cm) increment (cm) ment 1 0 6 12 18 24 30 36 42 48 54 60 66 72 78 84 90 96 102 108 114 120 132

2

3

0 15.0 24.1 30.0 34.0 37.0 39.0 40.5 41.3

15.0 9.1 5.9 4.0 3.0 2.0 1.5 0.8

4 0 20 54 98 126 146 154 152 138 122 106 92 79 64 52 40 30 20 14 10 6 0

5

0.8 3.0 5.9 15.0 9.1 4.0 2.0 1.5

1. (Column 6 is reversed sequence of column 5) 2. Infiltration loss = 0.15 cm/h = 0.9 cm/6 h

6

7

8

0 1.5 2.0 4.0 9.1 15.0 5.9 3.0 0.8

0 0.9 0.9 0.9 0.9 0.9 0.9 0.9 0.9

0 0.6 1.1 3.1 8.2 14.1 5.0 2.1 0

Floods

%

7.13 RISK, RELIABILITY AND SAFETY FACTOR Risk and Reliability The designer of a hydraulic structure always faces a nagging doubt about the risk of failure of his structure. This is because the estimation of the hydrologic design values (such as the design flood discharge and the river stage during the design flood) involve a natural or inbuilt uncertainty and as such a hydrological risk of failure. As an example, consider a weir with an expected life of 50 years and designed for a flood magnitude of return period T = 100 years. This weir may fail if a flood magnitude greater than the design flood occurs within the life period (50 years) of the weir. The probability of occurrence of an event (x ³ x T) at least once over a period of n successive years is called the risk, R . Thus the risk is given by R = 1 – (probability of non-occurrence of the event x ³ xT in n years) R = 1 – (1 – P)n

1 = 1 – æ1 - ö è Tø where

n

(7.29)

P = probability P (x ³ xT) =

T = return period The reliability Re, is defined as

1 T

n

1 (7.30) Re = 1 – R = æ 1 - ö è Tø It can be seen that the return period for which a structure should be designed depends upon the acceptable level of risk. In practice, the acceptable risk is governed by economic and policy considerations.

Safety Factor In addition to the hydrological uncertainty, as mentioned above, a water resource development project will have many other uncertainties. These may arise out of structural, constructional, operational and environmental causes as well as from non-technological considerations such as economic, sociological and political causes. As such, any water resource development project will have a safety factor for a given hydrological parameter M as defined below.

Actual value of the parameter M adopted in the design of the project Safety factor (for the parameter M ) = (S F )m = Value of the parameter M obtained from hydrological considerations only =

Cam Chm

(7.31)

The parameter M includes such items as flood discharge magnitude, maximum river stage, reservoir capacity and free board. The difference (Cam – Chm) is known as safety margin.

%

Engineering Hydrology

The concepts of risk, reliability and safety factor form the building blocks of the emerging field of reliability based design. EXAMPLE 7.11 A bridge has an expected life of 25 years and is designed for a flood magnitude of return period 100 years. (a) What is the risk of this hydrologic design? (b) If a 10% risk is acceptable, what return period will have to be adopted? SOLUTION:

æ

(a) The risk R = 1 – ç1 è

1ö ÷ Tø

n

Here n = 25 years and T = 100 years

R = 1 – çæ1 - 1 ÷ö è

100 ø

25

= 0.222

Hence the inbuilt risk in this design is 22.2%

æ

(b) If R = 10% = 0.10

0.10 = 1 – ç1 è

1ö ÷ Tø

25

25

æ1 - 1 ö = 0.90 and T = 238 years = say 240 years. èç T ø÷ Hence to get 10% acceptable risk, the bridge will have to be designed for a flood of return period T = 240 years.

EXAMPLE 7.12 Analysis of annual flood series of a river yielded a sample mean of 1000 m3/s and standard deviation of 500 m3/s. Estimate the design flood of a structure on this river to provide 90% assurance that the structure will not fail in the next 50 years. Use Gumbel’s method and assume the sample size to be very large. SOLUTION: Reliability

Also,

x = 1000 m3/s and sn–1 = 500 m3/s 50

1ö æ Re = 0.90 = ç1 - ÷ è Tø 1 1– = (0.90)1/50 = 0.997895 T T = 475 years xT = x + Ksn–1 é 475 ù yT = - êln × ln ú = 6.16226 (475 - 1) û ë 6.16226 - 0.577 = 4.355 K= 1.2825 xT = 1000 + (4.355) ´ 500 = 3177 m3/s

K=

yT - 0.577 1.2825

EXAMPLE 7.13 Annual flood data of the river Narmada at Garudeshwar covering the period 1948 to 1979 yielded for the annual flood discharges a mean of 29,600 m3/s and a standard deviation of 14,860 m3/s. For a proposed bridge on this river near this site it is decided to have an acceptable risk of 10% in its expected life of 50 years. (a) Estimate the flood discharge by Gumbel’s method for use in the design of this structure (b) If the actual flood value adopted in the design is 125,000 m3/s what are the safety factor and safety margin relating to maximum flood discharge? SOLUTION: Risk R = 0.10

Floods

%!

Life period of the structure n = 50 years Hence

R = 0.10 = 1 – æç1 - 1 ö÷ è ø

50

T

1ö æ 1/50 = 0.997895 çè1 - ÷ø = (1 – 0.10) T T = 475 years Gumbel’s method is now used to estimate the flood magnitude for this return period of T = 475 years. Record length N = 1948 to 1979 = 32 years

From Tables 7.3 and 7.4, yn = 0.5380 and Sn = 1.1193 é é 475 ù T ù yT = - ê ln. ln ú = - ê ln. ln ú = 6.16226 T - 1û (475 - 1) û ë ë yT - yn (6.16226 - 0.5380) = = 5.0248 K= 1.1193 Sn xT = xT + K sn–1 = 29600 + (5.0248 ´ 14860) = 104268 say = 105,000 m3/s = hydrological design flood magnitude

Actual flood magnitude adopted in the project is = 125,000 m3/s Safety factor = (SF)flood = 125,000/105,000 = 1.19 Safety margin for flood magnitude = 125,000 – 105,000 = 20,000 m3/s

REFERENCES 1. Central Water Commission, India, “Estimation of design flood peak”, Flood Estimation Directorate, Report No. 1/73, New Delhi, 1973. 2. Chow. V.T., Handbook of Applied Hydrology, McGraw-Hill, New York, NY, 1964. 3. Gray, D.M., Principles of Hydrology, Water Inf. Centre, Huntington, NY, 1970. 4. Indian Bureau of Standards, “Guidelines for fixing Spillway Capacity”, IS: 11223 – 1985. 5. Khushalani, K.B. and M. Khushalani, Irrigation Practice and Design. Vol. 1, Oxford & IBH, New Delhi, 1971. 6. Nemec, J., Engineering Hydrology, Tata McGraw-Hill, New Delhi, 1973. 7. Sokolov, A.A., S.E. Rantz, and M. Roche, Flood Computation— Methods Compiled from World Experience, The UNESCO Press, Paris, 1976. 8. UNO/WMO, “Assessment of magnitude and frequency of flood flows”, United Nations Pub., Water Resources Series No. 30, 1967.

REVISION QUESTIONS 7.1 Explain the rational method of computing the peak discharge of a small catchment. Where is this method commonly used and what are its merits and demerits? 7.2 Discuss the factors affecting the runoff coefficient C in rational formula. 7.3 What do you understand by time of concentration of a catchment? Describe briefly methods of estimation of the time of concentration. 7.4 What is the importance of time of concentration of a catchment in the estimation of flood by rational formula? 7.5 Annual flood series having N consecutive entries are available for a catchment. Describe a procedure to verify whether the data follow Gumbel’s distribution. 7.6 Write a brief note on frequency factor and its estimation in Gumbel’s method.

%" Engineering Hydrology 7.7

If the annual flood series data for a catchment are available for N consecutive years, explain a procedure to determine a flood discharge with a return period of T, (where T > N ), by using (a) Log-Pearson type III distribution, and (b) Log-normal distribution. 7.8 What are the limitations of flood frequency studies? 7.9 Explain briefly the following terms: (a) Design flood (b) Standard project flood (c) Probable maximum flood (d) Design storm 7.10 What are the recommended design floods for (a) Spillways of dams (b) Terrace outlets and vegetated waterways (c) Field diversions (d) Permanent barrages (e) Waterway for aqueducts 7.11 Explain briefly the following terms: (a) Risk (b) Reliability (c) Safety margin

PROBLEMS 7.1 A catchment of area 120 ha has a time of concentration of 30 min and runoff coefficient of 0.3. If a storm of duration 45 min results in 3.0 cm of rain over the catchment estimate the resulting peak flow rate. 7.2 Information on the 50-year storm is given below. Duration (minutes) Rainfall (mm)

15 40

30 60

45 75

60 100

180 120

A culvert has to drain 200 ha of land with a maximum length of travel of 1.25 km. The general slope of the catchment is 0.001 and its runoff coefficient is 0.20. Estimate the peak flow by the rational method for designing the culvert for a 50-year flood. 7.3 A basin is divided by 1-h isochrones into four sub-areas of size 200, 250, 350 and 170 hectares from the upstream end of the outlet respectively. A rainfall event of 5-h duration with intensities of 1.7 cm/h for the first 2 h and 1.25 cm/h for the next 3 h occurs uniformly over the basin. Assuming a constant runoff coefficient of 0.5, estimate the peak rate of runoff. (Note: An isochrone is a line on the catchment map joining points having equal time of travel of surface runoff. See Sec. 8.8.) 7.4 An urban catchment of area 3.0 km2 consists of 52% of paved areas, 20% parks, 18% multi-unit residential area. The remaining land use can be classified as light industrial area. The catchment is essentially flat and has sandy soil. If the time of concentration is 50 minutes, estimate the peak flow due to a design storm of depth 85 mm in 50 minutes. 7.5 In estimating the peak discharge of a river at a location X the catchment area was divided into four parts A, B, C and D. The time of concentration and area for different parts are as follows Part A B C D

Time of Concentration One Hour Two Hours Three Hours Four Hours

Area (in ha) 600 750 1000 1200

Records of a rain storm lasting for four hours as observed and the runoff factors during different hours are as follows:

Floods Time (in hours)

7.6

7.7

From

To

0 1 2 3

1 2 3 4

%#

Rainfall (mm)

Runoff factor

25.0 50.0 50.0 23.5

0.50 0.70 0.80 0.85

Calculate the maximum flow to be expected at X in m3/s assuming a constant base flow of 42.5 m3/s. A catchment area has a time of concentration of 20 minutes and an area of 20 ha. Estimate the peak discharge corresponding to return period of 25 yrs. Assume a runoff coefficient of 0.25. The intensity-duration-frequency for the storm in the area can be expressed by i = KTx/(D + a)n, where i = intensity in cm/h, T = retum period in years, and D = duration of storm in hours, with coefficients K = 6.93, x = 0.189, a = 0.50, n = 0.878. A 100 ha watershed has the following characteristics i. Maximum length of travel of water in the catchment = 3500 m ii. Difference in elevation between the most remote point on the catchment and the outlet = 65 m iii. Land use/cover details: Land use/cover

Area (ha)

Runoff coefficient

Forest Pasture Cuiltivated land

30 10 60

0.25 0.16 0.40

The maximum intensity – duration – frequency relationship for the watershed is given by 3.97 T 0.165 i= ( D + 0.15)0.733 where i = intensity in cm/h, T = Return period in years and D = duration of rainfall in hours. Estimate the 25-year peak runoff from the watershed that can be expected at the outlet of the watershed. 7.8 A rectangular paved area 150 m ´ 450 m has a longitudinal drain along one of its longer edges. The time of concentration for the area is estimated to be 30 minutes and consists of 25 minutes for over land flow across the pavement to the drain and 5 minutes for the maximum time from the upstream end of the drain to the outlet at the other end. (a) Construct the isochrones at 5 minutes interval for this area. (b) A rainfall of 7 cm/h occurs on this plot for D minutes and stops abruptly. Assuming a runoff coefficient of 0.8 sketch idealized outflow hydrographs for D = 5 and 40 minutes. 7.9 A rectangular parking lot is 150 m wide and 300 m long. The time of overland flow across the pavement to the longitudinal gutter along the centre is 20 minutes and the estimated total time of concentration to the downstream end of the gutter is 25 minutes. The coefficient of runoff is 0.92. If a rainfall of intensity 6 cm/h falls on the lot for 10 minutes and stops abruptly determine the peak rate of flow. 7.10 A flood of 4000 m3/s in a certain river has a return period of 40 years. (a) What is its probability of exceedence? (b) What is the probability that a flood of 4000 m3/s or greater magnitude may occur in the next 20 years? (c) What is the probability of occurrence of a flood of magnitude less than 4000 m3/s? 7.11 Complete the following: (a) Probability of a 10 year flood occurring at least once in the next 5 years is

%$ Engineering Hydrology (b) Probability that a flood of magnitude equal to or greater than the 20 year flood will not occur in the next 20 years is (c) Probability of a flood equal to or greater than a 50 year flood occurring next year is (d) Probability of a flood equal to or greater than a 50 year flood occurring three times in the next 10 years is (e) Probability of a flood equal to or greater than a 50 year flood occurring at least once in next 50 years is 7.12 A table showing the variation of the frequency factor K in the Gumbel’s extreme value distribution with the sample size N and return period T is often given in books. The following is an incomplete listing of K for T = 1000 years. Complete the table. Sample size, N 25 30 Value of K (T, N) for T = 1000 years 5.842 5.727

35

40

45

50

55

60

65

70

—

5.576

—

5.478

—

—

—

5.359

7.13 The following table gives the observed annual flood values in the River Bhagirathi at Tehri. Estimate the flood peaks with return periods of 50, 100 and 1000 years by using: (a) Gumbel’s extreme value distribution, (b) log-Pearson type III distribution, and (c) log-normal distribution Year Flood discharge m3/s

1963 3210

1964 4000

1965 1250

1966 3300

1967 2480

1968 1780

Year Flood discharge m3/s

1970 4130

1971 3110

1972 2320

1973 2480

1974 3405

1975 1820

1969 1860

7.14 A hydraulic structure on a stream has been designed for a discharge of 350 m3/s. If the available flood data on the stream is for 20 years and the mean and standard deviation for annual flood series are 121 and 60 m3/s respectively, calculate the return period for the design flood by using Gumbel’s method. 7.15 In a frequency analysis of rainfall based on 15 years of data of 10 minutes storm, the following values were obtained: Arithmetic mean of data = 1.65 cm Standard deviation = 0.45 cm Using Gumbel’s extremal distribution, find the recurrence interval of a storm of 10 minutes duration and depth equal to 3.0 cm. Assume the sample size to be very large. 7.16 For a data of maximum-recorded annual floods of a river the mean and the standard deviation are 4200 m3/s and 1705 m3/s respectively. Using Gumbel’s extreme value distribution, estimate the return period of a design flood of 9500 m3/s. Assume an infinite sample size. 7.17 The flood data of a river was analysed for the prediction of extreme values by LogPearson Type III distribution. Using the variate z = log Q, where Q = flood discharge in the river, it was found that z = 2.510, sz = 0.162 and coefficient of skew Cs = 0.70. (a) Estimate the flood discharges with return periods of 50, 100, 200 and 1000 years in this river. (b) What would be the corresponding flood discharge if log-normal distribution was used? 7.18 The frequency analysis of flood data of a river by using Log Pearson Type III distribution yielded the following data: Coefficient of Skewness = 0.4 Return Period (T) (in yrs) 50 200

Peak Flood (m3/s) 10,000 15,000

Floods

%%

Given the following data regarding the variation of the frequency factor K with the return period T for Cs = 0.4, estimate the flood magnitude in the river with a return period of 1000 yrs. Return Period (T) : Frequency Factor (K) :

50 2.261

200 2.949

1000 3.670

7.19 A river has 40 years of annual flood flow record. The discharge values are in m3/s. The logarithms to base 10 of these discharge values show a mean value of 3.2736, standard deviation of 0.3037 and a coefficient of skewness of 0.07. Calculate the 50 year return period annual flood discharge by, (a) Log-normal distribution and (b) Log-Pearson type III distribution. 7.20 The following data give flood-data statistics of two rivers in UP: S. No.

River

Length of records (years)

Mean annual flood (m3/s)

sn–1

1 2

Ganga at Raiwala Yamuna at Tajewala

92 54

6437 5627

2951 3360

(a) Estimate the 100 and 1000 year floods for these two rivers by using Gumbel’s method. (b) What are the 95% confidential intervals for the predicted values? 7.21 For a river, the estimated flood peaks for two return periods by the use of Gumbel’s method are as follows: Return Period (years)

Peak flood (m3/s)

100 50

435 395

What flood discharge in this river will have a return period of 1000 years? 7.22 Using 30 years data and Gumbel’s method the flood magnitudes, for return periods of 100 and 50 years for a river are found to be 1200 and 1060 m3/s respectively. (a) Determine the mean and standard deviation of the data used, and (b) Estimate the magnitude of a flood with a return period of 500 years. 7.23 The ordinates of a mass curve of rainfall from a severe storm in a catchment is given. Ordinates of a 12-h unit hydrograph applicable to the catchment are also given. Using the given mass curve, develop a design storm to estimate the design flood for the catchment. Taking the f index as 0.15 cm/h, estimate the resulting flood hydrograph. Assume the base flow to be 50 m3/s. Time (h) Cumulative rainfall (cm) 12-h UH ordinate (m3/s)

0 0 0

12

24

36

48 60 72

84

96 108 120 132

50

30 15

10.2 30.5 34.0 36.0 32

96

130

126 98 75

7

3

7.24 A 6-hour unit hydrograph is in the form of a triangle with a peak of 50 m /s at 24 hours from start. The base is 54 hours. The ordinates of a mass curve of rainfall from a severe storm in the catchment is as below: Time (h) Cumulative Rainfall (cm)

0 0

6 5

12 12

18 15

24 17.6

Using this data, develop a design storm and estimate the design flood for the catchment. Assume f index = 0.10 cm/h and the base flow = 20 m3/s.

%& Engineering Hydrology 7.25 A water resources project has an expected life of 20 years. (a) For an acceptable risk of 5% against the design flood, what design return period is to be adopted? (b) If the above return period is adopted and the life of the structure can be enhanced to 50 years, what is the new risk value? 7.26 A factory is proposed to be located on the edge of the 50 year flood plain of a river. If the design life of the factory is 25 years, what is the reliability that it will not be flooded during its design life? 7.27 A spillway has a design life of 20 years. Estimate the required return period of a flood if the acceptable risk of failure of the spillway is 10% (a) in any year, and (b) over its design life. 7.28 Show that if the life of a project n has a very large value, the risk of failure is 0.632 when the design period is equal to the life of the project, n.

æ

n

(Hint: Show that ç1 - ÷ = e–1 for large values of n) è nø 7.29 The regression analysis of a 30 year flood data at a point on a river yielded sample mean of 1200 m3/s and standard deviation of 650 m3/s. For what discharge would you design the structure to provide 95% assurance that the structure would not fail in the next 50 years? Use Gumbel’s method. The value of the mean and standard deviation of the reduced variate for N = 30 are 0.53622 and 1.11238 respectively. 7.30 Analysis of the annual flood peak data of river Damodar at Rhondia, covering a period of 21 years yielded a mean of 8520 m3/s and a standard deviation of 3900 m3/s. A proposed water control project on this river near this location is to have an expected life of 40 years. Policy decision of the project allows an acceptable reliability of 85%. (a) Using Gumbel’s method recommend the flood discharge for this project. (b) If a safety factor for flood magnitude of 1.3 is desired, what discharge is to be adopted? What would be the corresponding safety margin?

OBJECTIVE QUESTIONS 7.1 A culvert is designed for a peak flow Qp on the basis of the rational formula. If a storm of the same intensity as used in the design but of duration twice larger occurs the resulting peak discharge will be (a) Qp (b) 2 Qp (c) Qp/2 (d) Q 2p 7.2 A watershed of area 90 ha has a runoff coefficient of 0.4. A storm of duration larger than the time of concentration of the watershed and of intensity 4.5 cm/h creates a peak discharge of (a) 11.3 m3/s (b) 0.45 m3/s (c) 450 m3/s (d) 4.5 m3/s 7.3 A rectangular parking lot, with direction of overland flow parallel to the larger side, has a time of concentration of 25 minutes. For the purpose of design of drainage, four rainfall patterns as below are to be considered. A = 35 mm/h for 15 minutes, B = 45 mm/h for 10 minutes, C = 10 mm/h for 60 minutes, D = 15 mm/h for 25 minutes, The greatest peak rate of runoff is expected in the storm (a) A (b) B (c) C (d) D 7.4 For an annual flood series arranged in decreasing order of magnitude, the return period for a magnitude listed at position m in a total of N entries, by Weibull formula is (a) m/N (b) m/(N + 1) (c) (N + 1)/m (d) N/(m + 1). 7.5 The probability that a hundred year flood may not occur at all during the 50 year life of a project is (a) 0.395 (b) 0.001 (c) 0.605 (d) 0.133 7.6 The probability of a flood, equal to or greater than 1000 year flood, occurring next year is (a) 0.0001 (b) 0.001 (c) 0.386 (d) 0.632

Floods 7.7 7.8 7.9 7.10 7.11

7.12

7.13

7.14 7.15

7.16

7.17 7.18

7.19 7.20

%'

The probability of a flood equal to or greater than 50 year flood, occurring at least one in next 50 years is (a) 0.02 (b) 0.636 (c) 0.364 (d) 1.0 The general equation for hydrological frequency analysis states that xT = value of a variate with a return period of T years is given by xT = (a) x – Ks (b) x /Ks (c) Ks (d) x + Ks For a return period of 100 years the Gumbel’s reduced variate yT is (a) 0.0001 (b) 0.001 (c) 0.386 (d) 0.632 An annual flood series contains 100 years of flood data. For a return period of 200 years the Gumbel’s reduced variate can be taken as (a) 5.296 (b) –4.600 (c) 1.2835 (d) 0.517 To estimate the flood magnitude with a return period of T years by the Log–Pearson Type III method, the following data pertaining to annual flood series is sufficient (a) Mean, standard deviation and coefficient of skew of discharge data (b) Mean and standard deviation of the log of discharge and the number of years of data (c) Mean, standard deviation and coefficient of skew of log of discharge data (d) Mean and standard deviation of the log of discharges If the recurrence interval of an event is TA in annual series and Tp in partial duration series, then (a) TA is always smaller than Tp (b) Difference between TA and Tp is negligible for TA < 5 years (c) Difference between TA and Tp is negligible for TA > 10 years (d) Difference between TA and Tp is not negligible till TA > 100 years The term mean annual flood denotes (a) Mean floods in partial-duration series (b) Mean of annual flood flow series (c) A flood with a recurrence interval of 2.33 years (d) A flood with a recurrence interval of N/2 years, where N = number of years of record. The use of unit hydrographs for estimating floods is generally limited to catchments of size less than (b) 500 km2 (c) 106 km2 (d) 5000 ha (a) 5000 km2 The probable maximum flood is (a) The standard project flood of an extremely large river (b) A flood adopted in the design of all kinds of spillways (c) An extremely large but physically possible flood in the region (d) The maximum possible flood that can occur anywhere in the country The standard project flood is (a) Smaller than probable maximum flood in the region (b) The same as the design flood used for all small hydraulic structures (c) Larger than the probable maximum flood by a factor implying factor of safety (d) The same as the probable maximum flood A hydraulic structure has been designed for a 50 year flood. The probability that exactly one flood of the design capacity will occur in the 75 year life of the structure is (a) 0.02 (b) 0.220 (c) 0.336 (d) 0.780 The return period that a designer must use in the estimation of a flood for a hydraulic structure, if he is willing to accept 20% risk that a flood of that or higher magnitude will occur in the next 10 years is (a) 95 years (b) 75 years (c) 45 years (d) 25 years A hydraulic structure with a life of 30 years is designed for a 30 year flood. The risk of failure of the structure during its life is (a) 0.033 (b) 0.638 (c) 0.362 (d) 1.00 A bridge is designed for a 50 year flood. The probability that only one flood of the design capacity or higher will occur in the 75 years life of the bridge is (a) 0.020 (b) 0.220 (c) 0.786 (d) 0.336

Chapter

8

FLOOD ROUTING

8.1 INTRODUCTION The flood hydrograph discussed in Chap. 6 is in fact a wave. The stage and discharge hydrographs represent the passage of waves of the river depth and discharge respectively. As this wave moves down the river, the shape of the wave gets modified due to various factors, such as channel storage, resistance, lateral addition or withdrawal of flows, etc. When a flood wave passes through a reservoir, its peak is attenuated and the time base is enlarged due to the effect of storage. Flood waves passing down a river have their peaks attenuated due to friction if there is no lateral inflow. The addition of lateral inflows can cause a reduction of attenuation or even amplification of a flood wave. The study of the basic aspects of these changes in a flood wave passing through a channel system forms the subject matter of this chapter. Flood routing is the technique of determining the flood hydrograph at a section of a river by utilizing the data of flood flow at one or more upstream sections. The hydrologic analysis of problems such as flood forecasting, flood protection, reservoir design and spillway design invariably include flood routing. In these applications two broad categories of routing can be recognised. These are: 1. Reservoir routing, and 2. Channel routing. In Reservoir routing the effect of a flood wave entering a reservoir is studied. Knowing the volume-elevation characteristic of the reservoir and the outflow-elevation relationship for the spillways and other outlet structures in the reservoir, the effect of a flood wave entering the reservoir is studied to predict the variations of reservoir elevation and outflow discharge with time. This form of reservoir routing is essential (i) in the design of the capacity of spillways and other reservoir outlet structures, and (ii) in the location and sizing of the capacity of reservoirs to meet specific requirements. In Channel routing the change in the shape of a hydrograph as it travels down a channel is studied. By considering a channel reach and an input hydrograph at the upstream end, this form of routing aims to predict the flood hydrograph at various sections of the reach. Information on the flood-peak attenuation and the duration of high-water levels obtained by channel routing is of utmost importance in flood-forecasting operations and flood-protection works. A variety of routing methods are available and they can be broadly classified into two categories as: (i) hydrologic routing, and (ii) hydraulic routing. Hydrologic-routing methods employ essentially the equation of continuity. Hydraulic methods, on the other hand, employ the continuity equation together with the equation of motion of unsteady flow. The basic differential equations used in the hydraulic routing, known as St. Venant equations afford a better description of unsteady flow than hydrologic methods.

Flood Routing

281

8.2 BASIC EQUATIONS The passage of a flood hydrograph through a reservoir or a channel reach is an unsteady-flow phenomenon. It is classified in open-channel hydraulics as gradually varied unsteady flow. The equation of continuity used in all hydrologic routing as the primary equation states that the difference between the inflow and outflow rate is equal to the rate of change of storage, i.e. dS I–Q= (8.1) dt where I = inflow rate, Q = outflow rate and S = storage. Alternatively, in a small time interval Dt the difference between the total inflow volume and total outflow volume in a reach is equal to the change in storage in that reach

I Dt – Q Dt = DS (8.2) where I = average inflow in time Dt, Q = average outflow in time Dt and DS = change in storage. By taking I = (I 1 + I 2)/2, Q = (Q 1 + Q 2)/2 and DS = S2 – S1 with suffixes 1 and 2 to denote the beginning and end of time interval Dt, Eq. (8.2) is written as æ I1 + I 2 ö æ Q1 + Q2 ö (8.3) çè ÷ø D t - çè ÷ D t = S2 – S1 2 2 ø The time interval Dt should be sufficiently short so that the inflow and outflow hydrographs can be assumed to be straight lines in that time interval. Further Dt must be shorter than the time of transit of the flood wave through the reach. In the differential form the equation of continuity for unsteady flow in a reach with no lateral flow is given by ¶Q ¶y +T =0 (8.4) ¶x ¶t where T = top width of the section and y = depth of flow. The equation of motion for a flood wave is derived from the application of the momentum equation as ¶y V ¶V 1 ¶V = S0 – Sf (8.5) + + ¶x g ¶x g ¶t where V = velocity of flow at any section, S0 = channel bed slope and Sf = slope of the energy line. The continuity equation [Eq. (8.4)] and the equation of motion [Eq. (8.5)] are believed to have been first developed by A.J.C. Barrè de Saint Venant (1871) and are commonly known as St. Venant equations. Hydraulic-flood routing involves the numerical solution of St.Venant equations. Details about these equations, such as their derivations and various forms are available in Ref. 9.

8.3

HYDROLOGIC STORAGE ROUTING (LEVEL POOL ROUTING)

A flood wave I(t) enters a reservoir provided with an outlet such as a spillway. The outflow is a function of the reservoir elevation only, i.e. Q = Q(h). The storage in the reservoir is a function of the reservoir elevation, S = S(h). Further, due to the passage of the flood wave through the reservoir, the water level in the reservoir changes with time, h = h(t) and hence the storage and discharge change with time (Fig. 8.1). It is

282 Engineering Hydrology required to find the variation of S, h and Q with time, i.e. find S = S(t), Q = Q(t) and h = h(t) given I = I(t). If an uncontrolled spillway is provided in a resFig. 8.1 Storage routing (Schematic) ervoir, typically 2 Q = Cd 2 g Le H 3/ 2 = Q(h) 3 where H = head over the spillway, Le = effective length of the spillway crest and Cd = coefficient of discharge. Similarly, for other forms of outlets, such as gated spillways, sluice gates, etc. other relations for Q(h) will be available. For reservoir routing, the following data have to be known: l Storage volume vs elevation for the reservoir; l Water-surface elevation vs outflow and hence storage vs outflow discharge; l Inflow hydrograph, I = I(t); and l Initial values of S, I and Q at time t = 0. There are a variety of methods available for routing of floods through a reservoir. All of them use Eq. (8.2) but in various rearranged manners. As the horizontal water surface is assumed in the reservoir, the storage routing is also known as Level Pool Routing. Two commonly used semi-graphical methods and a numerical method are described below.

Modified Pul’s Method Equation (8.3) is rearranged as

Q1 D t ö æ Q2 D t ö æ I1 + I 2 ö æ (8.6) çè ÷ D t + çè S1 ÷ = ç S2 + ÷ 2 ø 2 ø è 2 ø At the starting of flood routing, the initial storage and outflow discharges are known. In Eq. (8.6) all the terms in the left-hand side are known at the beginning of a time step Dt. Hence the value of the function æç S + Q2 D t ö÷ at the end of the time step is calcuè 2 2 ø QD t ö æ lated by Eq. (8.6). Since the relation S = S(h) and Q = Q(h) are known, ç S + ÷ è 2 ø2 will enable one to determine the reservoir elevation and hence the discharge at the end of the time step. The procedure is repeated to cover the full inflow hydrograph. For practical use in hand computation, the following semigraphical method is very convenient. 1. From the known storage-elevation and discharge-elevation data, prepare a curve QD t ö æ of ç S + ÷ vs elevation (Fig. 8.2). Here Dt is any chosen interval, approxiè 2 ø mately 20 to 40% of the time of rise of the inflow hydrograph. 2. On the same plot prepare a curve of outflow discharge vs elevation (Fig. 8.2). 3. The storage, elevation and outflow discharge at the starting of routing are known.

Flood Routing

283

Fig. 8.2 Modified Pul’s method of storage routing

Q1 D t ö æ I1 + I 2 ö æ For the first time interval Dt, ç Dt and ç S1 + ÷ are known and è 2 ÷ø è 2 ø Q2 D t ö æ hence by Eq. (8.6) the term ç S2 + ÷ is determined. è 2 ø Q2 D t ö æ 4. The water-surface elevation corresponding to ç S2 + ÷ is found by using è 2 ø the plot of step (1). The outflow discharge Q2 at the end of the time step Dt is found from plot of step (2). Q2 D t ö QD t ö æ æ 5. Deducting Q2 D t from ç S2 + ÷ for the beginning of ÷ gives çè S è ø 2 ø1 2 the next time step. 6. The procedure is repeated till the entire inflow hydrograph is routed. EXAMPLE 8.1 A reservoir has the following elevation, discharge and storage relationships: Elevation (m)

Storage (106 m3)

Outflow discharge (m3/s)

100.00 100.50 101.00 101.50 102.00 102.50 102.75 103.00

3.350 3.472 3.380 4.383 4.882 5.370 5.527 5.856

0 10 26 46 72 100 116 130

284 Engineering Hydrology When the reservoir level was at 100.50 m, the following flood hydrograph entered the reservoir. Time (h) 0 3 Discharge (m /s) 10

6 20

12 55

18 80

24 73

30 58

36 46

42 36

48 55

54 20

60 15

66 13

72 11

Route the flood and obtain (i) the outflow hydrograph and (ii) the reservoir elevation vs time curve during the passage of the flood wave.

SOLUTION: A time interval Dt = 6 h is chosen. From the available data the elevationQD t ö æ discharge – ç S + ÷ table is prepared. è 2 ø Dt = 6 ´ 60 ´ 60 = 0.0216 ´ 106 s

Elevation (m) 100.00 100.50 101.00 101.50 102.00 102.50 102.75 103.00 3 Dischange Q (m /s) 0 10 26 46 72 100 116 130

QD t ö æ 3 S+ ÷ (Mm ) èç 2 ø

3.35

3.58

4.16

4.88

5.66

6.45

6.78

7.26

QD t ö æ A graph of Q vs elevation and ç S + ÷ vs elevation is prepared (Fig. 8.2). At the start è 2 ø QD t ö æ 3 of routing, elevation = 100.50 m, Q = 10.0 m3/s, and ç S ÷ = 3.362 Mm . Starting è 2 ø QD t ö æ from this value of ç S ÷ , Eq. (8.6) is used to get è 2 ø step of 6 h as

QD t ö æ çè S + ÷ at the end of first time 2 ø

Dt æ QD t ö QD t ö æ 0.0216 + çS + (3.362) = 3.686 Mm3. ÷ = (10 + 20) ´ çè S + ÷ø = (I1 + I2) 2 è 2 ø1 2 2 2

QD t ö æ Looking up in Fig. 8.2, the water-surface elevation corresponding to ç S + ÷ = è 2 ø 3.686 Mm3 is 100.62 m and the corresponding outflow discharge Q is 13 m3/s. For the QD t ö QD t ö æ æ next step, Initial value of ç S ÷ = èç S + ÷ of the previous step – Q Dt è ø 2 2 ø = (3.686 – 13 ´ 0.0216) = 3.405 Mm3 The process is repeated for the entire duration of the inflow hydrograph in a tabular form as shown in Table 8.1. Using the data in columns 1, 8 and 7, the outflow hydrograph (Fig. 8.3) and a graph showing the variation of reservoir elevation with time (Fig. 8.4) are prepared. QD t ö æ Sometimes a graph of ç S ÷ vs elevation prepared from known data is plotted in è 2 ø Fig. 8.2 to aid in calculating the items in column 5. Note that the calculations are sequential in nature and any error at any stage is carried forward. The accuracy of the method depends upon the value of Dt; smaller values of Dt give greater accuracy.

285

Flood Routing

Table 8.1 Flood Routing through a Reservoir—Modified Pul’s method— Example 8.1 Dt = 6 h = 0.0216 Ms, I = (I1 + I2)/2 S–

D tQ

Time

Inflow

I

I × Dt

(h)

I (m3/s)

(m3/s)

(Mm3)

2 (Mm3)

1

2

3

4

5

10

6

20

12

55

18

80

24

73

30

58

36

46

42

36

48

27.5

54

20

60

15

66

13

72

11

S+

D tQ

2 (Mm3)

6

15.00

0.324

3.362

3.636

37.50

0.810

3.405

4.215

67.50

1.458

3.632

5.090

76.50

1.652

3.945

5.597

65.50

1.415

4.107

5.522

52.00

1.123

4.096

5.219

41.00

0.886

3.988

4.874

31.75

0.686

3.902

4.588

23.75

0.513

3.789

4.302

17.50

0.378

3.676

4.054

14.00

0.302

3.557

3.859

12.00

0.259

3.470

3.729

3.427

Elevation

Q

(m)

(m3/s)

7

8

100.50

10

100.62

13

101.04

27

101.64

53

101.96

69

101.91

66

101.72

57

101.48

48

101.30

37

100.10

25

100.93

23

100.77

18

100.65

14

Fig. 8.3 Variation of inflow and outflow discharges—Example 8.1

286 Engineering Hydrology

Fig. 8.4 Variation of reservoir elevation with time—Example 8.1

Goodrich Method Another popular method of hydrologic reservoir routing, known as Goodrich method utilizes Eq. (8.3) rearranged as 2 S2 2 S1 I1 + I2 – Q1 – Q2 = Dt Dt where suffixes 1 and 2 stand for the values at the beginning and end of a time step Dt respectively. Collecting the known and initial values together, æ 2 S1 ö æ 2 S2 ö (I1 + I2) + ç - Q1 ÷ = ç + Q2 ÷ è Dt ø è Dt ø

(8.7)

2S For a given time step, the left-hand side of Eq. 8.7 is known and the term æç + Q ö÷ è Dt ø2

is determined by using Eq. (8.7). From the known storage-elevation-discharge data, 2S the function æç + Q ö÷ is established as a function of elevation. Hence, the disè Dt ø2 charge, elevation and storage at the end of the time step are obtained. For the next time step,

éæ 2 S ù ö êçè D t + Q ÷ø - 2 Q 2 ú of the previous time step 2 ëê ûú 2S = æç - Q ö÷ for use as the initial values è Dt ø1

The procedure is illustrated in Example 8.2. EXAMPLE 8.2 Route the following flood hydrograph through the reservoir of Example 8.1 by the Goodrich method: Time (h) 0 Inflow (m3/s) 10

6 30

12 85

18 140

24 125

30 96

36 75

42 60

48 46

54 35

The initial conditions are: when t = 0, the reservoir elevation is 100.60 m.

60 25

66 20

Flood Routing

287

SOLUTION: A time increment Dt = 6 h = 0.0216 Ms is chosen. Using the known storage-elevation-discharge data, the following table is prepared.

æ 2S ö + Q÷ vs elevation is prepared from this A graph depicting Q vs elevation and ç è Dt ø data (Fig. 8.5). Elevation (m) 100.00 100.50 101. 00 101.50 102.00 102.50 102.75 103.00 3 Outflow Q (m /s) 0 10 26 46 72 100 116 130

æ 2S ö 3 çè D t + Q÷ø (m /s)

310.2

331.5

385.3

451.8

524.0

597.2

627.8

At t = 0, Elevation = 100.60 m, from Fig. 8.5, Q = 12 m3/s and

æ 2S ö 3 çè D t + Q÷ø = 340 m /s æ 2 S - Qö = 340 – 24 = 316 m3/s çè D t ÷ø 1

For the first time interval of 6 h, I1 = 10, I2 = 30, Q1 = 12, and æ 2 S + Qö = (10 + 30) + 316 = 356 m3/s çè D t ÷ø 2

Fig. 8.5 Goodrich method of storage routing—Example 8.2

672.2

288 Engineering Hydrology 2S From Fig. 8.5 the reservoir elevation for this æç + Qö÷ is 100.74 m è Dt ø2 For the next time increment æ 2 S - Qö = 356 – 2 ´ 17 = 322 m3/s çè D t ÷ø 1

The procedure is repeated in a tabular form (Table 8.2) till the entire flood is routed. Using the data in columns 1, 7 and 8, the outflow hydrograph and a graph showing the variation of reservoir elevation with time (Fig. 8.6) are plotted. In this method also, the accuracy depends upon the value of Dt chosen; smaller values of Dt give greater accuracy.

Table 8.2 Reservoir Routing—Goodrich Method—Example 8.2 Dt = 6.0 h = 0.0216 Ms Time

I

(h)

(m3/s)

1

2

10

6

30

12

85

18

140

24

125

30

96

36

75

42

60

48

46

54

35

60

25

66

20

æ 2S ö çè D t - Q÷ø

æ 2S ö çè D t + Q÷ø

Elevation

Discharge Q

(m3/s)

(m3/s)

(m)

(m3/s)

4

5

6

7

40

316

(340) 356

115

322

437

225

357

582

265

392

657

221

403

624

171

400

571

135

391

526

106

380

486

81

372

453

60

361

421

45

347

392

(I1 + I2)

3

335

100.6

12

100.74

17

101.38

40

102.50

95

102.92

127

102.70

112

102.32

90

102.02

73

101.74

57

101.51

46

101.28

37

101.02

27

Standard Fourth-Order Runge-Kutta Method (SRK) The Pul’s method and Goodrich method of level pool routing are essentially semigraphical methods. While they can be used for writing programs for use in a computer, a more efficient computation procedure can be achieved by use of any of the Runge-

Flood Routing

289

Fig. 8.6 Results of reservoir routing—Example 8.2 Kutta methods. The standard fourth-order Runge-Kutta method (SRK) is the most accurate one. Designating S = storage at a water surface elevation H in the reservoir = S (H) A = area of the reservoir at elevation H = function of H = A (H) Q = outflow from the reservoir = function of H = Q (H) dS = A (H) × dH (8.8) By continuity equation

dS dH = I(t) – Q(H) = A(H) dt dt I (t ) - Q ( H ) dH = = Function of (t, H) = F(t, H) (8.9) dt A(H ) If the routing is conducted from the initial condition, (at t = t0 and I = I0; Q = Q0, H = H0, S = S0) in time steps Dt, the water surface elevation H at (i + 1)th step is given in SRK method as 1 (8.10) Hi+1 = Hi + (K1 + 2K2 + 2K3 + K4) Dt 6 where K1 = F(ti, Hi) Dt æ ö 1 K2 = F ç ti + , H i + K1 D t ÷ è ø 2 2 Dt æ ö 1 K3 = F ç ti + , H i + K2 D t ÷ è ø 2 2 K4 = F(ti + Dt, Hi + K3 Dt) In Eq. (8.10) the suffix i denotes the values at the ith step, and suffix (i + 1) denotes the values at the (i + 1)th step. At i = 1 the initial conditions I0, Q0, S0 and H0 prevail. Starting from the known initial conditions and knowing Q vs H and A vs H relationships, a given hydrograph I = I(t) is routed by selecting a time step Dt. At any time t = (t0 + i Dt), the value of Hi is known and the coefficients K1, K2, K3, K4 are determined by repeated appropriate evaluation of the function F(t, H). It is seen that the SRK method directly determines Hi + 1 by four evaluations of the function F (t, H).

290 Engineering Hydrology Knowing the values of H at various time intervals, i.e. H = H(t), the other variables Q(H) and S (H) can be calculated to complete the routing operation. Developing a computer program for level pool routing by using SRK is indeed very simple. Other Methods In addition to the above two methods, there are a large number of other methods which depend on different combinations of the parameters of the basic continuity equation [Eq. (8.3)]. A third order Runge-Kutta method for level pool routing is described in Ref. 3.

8.4 ATTENUATION Figures 8.3 and 8.6 show the typical result of routing a flood hydrograph through a reservoir. Owing to the storage effect, the peak of the outflow hydrograph will be smaller than that of the inflow hydrograph. This reduction in the peak value is called attenuation. Further, the peak of the outflow occurs after the peak of the inflow; the time difference between the two peaks is known as lag. The attenuation and lag of a flood hydrograph at a reservoir are two very important aspects of a reservoir operating under a flood-control criterion. By judicious management of the initial reservoir level at the time of arrival of a critical flood, considerable attenuating of the floods can be achieved. The storage capacity of the reservoir and the characteristics of spillways and other outlets controls the lag and attenuation of an inflow hydrograph. In Figs. 8.3 and 8.6 in the rising part of the outflow curve where the inflow curve is higher than the outflow curve, the area between the two curves indicate the accumulation of flow as storage. In the falling part of the outflow curve, the outflow curve is higher than the inflow curve and the area between the two indicate depletion from the storage. When the outflow from a storage reservoir is uncontrolled, as in a freely operating spillway, the peak of the outflow hydrograph will occur at the point of intersection of the inflow and outflow curves (Figs. 8.3 and 8.6), as proved in Example 8.3. EXAMPLE 8.3 Show that in the level pool routing the peak of the outflow hydrograph must intersect the inflow hydrograph. SOLUTION: S = a function of water surface elevation in the reservoir = S(H) dS dH = A dt dt where A = area of the reservoir at elevation H. Outflow Q = function of H = Q(H) dQ dS At peak outflow = 0, hence =0 dt dt dH dS = 0, =0 Also, when dt dt dS By continuity equation I – Q = dt dS When = 0, I = Q dt Hence, when the peak outflow occurs, I = Q and thus the peak of the outflow hydrograph must intersect the inflow hydrograph (Figs. 8.3 and 8.6).

Flood Routing

291

8.5 HYDROLOGIC CHANNEL ROUTING In reservoir routing presented in the previous sections, the storage was a unique function of the outflow discharge, S = f (Q). However, in channel routing the storage is a function of both outflow and inflow discharges and hence a different routing method is needed. The flow in a river during a flood belongs to the category of gradually varied unsteady flow. The water surface in a channel reach is not only not parallel to the channel bottom but also varies with time (Fig. 8.7). Considering a channel reach having a flood flow, the total volume in storage can be considered under two categories as 1. Prism storage 2. Wedge storage

Fig. 8.7 Storage in a channel reach

Prism Storage It is the volume that would exist if the uniform flow occurred at the downstream depth, i.e. the volume formed by an imaginary plane parallel to the channel bottom drawn at the outflow section water surface.

Wedge Storage It is the wedge-like volume formed between the actual water surface profile and the top surface of the prism storage. At a fixed depth at a downstream section of a river reach, the prism storage is constant while the wedge storage changes from a positive value at an advancing flood to a negative value during a receding flood. The prism storage Sp is similar to a reservoir and can be expressed as a function of the outflow discharge, Sp = f (Q). The wedge storage can be accounted for by expressing it as Sw = f (I). The total storage in the channel reach can then be expressed as S = K[x Im + (1 – x)Qm] (8.11)

292 Engineering Hydrology where K and x are coefficients and m = a constant exponent. It has been found that the value of m varies from 0.6 for rectangular channels to a value of about 1.0 for natural channels.

Muskingum Equation Using m = 1.0, Eq. (8.11) reduces to a linear relationship for S in terms of I and Q as S = K [x I + (1 – x) Q] (8.12) and this relationship is known as the Muskingum equation. In this the parameter x is known as weighting factor and takes a value between 0 and 0.5. When x = 0, obviously the storage is a function of discharge only and Eq. (8.12) reduces to S = KQ (8.13) Such a storage is known as linear storage or linear reservoir. When x = 0.5 both the inflow and outflow are equally important in determining the storage. The coefficient K is known as storage-time constant and has the dimensions of time. It is approximately equal to the time of travel of a flood wave through the channel reach.

Estimation of K and x Figure 8.8 shows a typical inflow and outflow hydrograph through a channel reach. Note that the outflow peak does not occur at the point of intersection of the inflow and outflow hydrographs. Using the continuity equation [Eq. (8.3)], (I1 + I2)

Dt

– (Q1 +Q2)

Dt

= DS 2 2 the increment in storage at any time t and time element Dt can be calculated. Summation of the various incremental storage values enable one to find the channel storage S vs time t relationship (Fig. 8.8). If an inflow and outflow hydrograph set is available for a given reach, values of S at various time intervals can be determined by the above technique. By choosing a trial value of x, values of S at any time t are plotted against the corresponding [x I + (1 – x) Q] values. If Fig. 8.8 Hydrographs and storage in channel routing the value of x is chosen correctly, a straight-line relationship as given by Eq. (8.12) will result. However, if an incorrect value of x is used, the plotted points will trace a looping curve. By trial and error, a value of x is so chosen that the data very nearly describe a straight line (Fig 8.9). The inverse slope of this straight line will give the value of K. Normally, for natural channels, the value of x lies between 0 to 0.3. For a given reach, the values of x and K are assumed to be constant.

Flood Routing

293

EXAMPLE 8.4 The following inflow and outflow hydrographs were observed in a river reach. Estimate the values of K and x applicable to this reach for use in the Muskingum equation. Time (h) Inflow (m3/s) Outflow (m3/s)

0 5 5

6 20 6

12 50 12

18 50 29

24 32 38

30 22 35

36 15 29

42 10 23

48 7 17

54 5 13

60 66 5 5 9 7

SOLUTION: Using a time increment Dt = 6 h, the calculations are performed in a tabular manner as in Table 8.3. The incremental storage DS and S are calculated in columns 6 and 7 respectively. It is advantageous to use the units [(m3/s).h] for storage terms. As a first trial x = 0.30 is selected and the value of [x I+ (1 – x) Q] evaluated (column 8) and plotted against S in Fig. 8.9. Since a looped curve is obtained, further trials are performed with x = 0.35 and 0.25. It is seen from Fig. 8.9 that for x = 0.25 the data very nearly describe a straight line and as such x = 0.25 is taken as the appropriate value for the reach. From Fig. 8.9, K = 13.3 h

Fig. 8.9 Determination of K and x for a channel reach

Muskingum Method of Routing For a given channel reach by selecting a routing interval Dt and using the Muskingum equation, the change in storage is S2 – S1 = K[x (I2 – I1)+(1 – x) (Q2 – Q1)] (8.14) where suffixes 1 and 2 refer to the conditions before and after the time interval Dt. The continuity equation for the reach is

294 Engineering Hydrology Table 8.3 Determination of K and x—Example 8.4 Storage in (m3/s) × h

Dt = 6 h, Time I Q (I – Q) Average DS = S= (h) (m3/s) (m3/s) (I – Q) Col. 5 ´ Dt S D S (m3/s × h) (m3/s × h) 1

2

3

4

5

5

6

20

6

14

12

50

12

38

18

50

29

21

24

32

38

–6

30

22

35

–13

36

15

29

–14

42

10

23

–13

48

7

17

–10

54

5

13

–8

60

5

9

–4

66

5

7

–2

5

6

7.0

42

26.0

156

29.5

177

7.5

45

–9.5

–57

–13.5

–81

–13.5

–81

–11.5

–69

–9.0

–54

–6.0

–36

–3.0

–18

[x I + (1 – x) Q] (m3/s) x= x= x= 0.35 0.30 0.25

7

8

9

10

5.0

5.0

5.0

42

10.9

10.2

9.5

198

25.3

23.4 21.5

375

36.4

35.3 34.3

420

35.9

36.2 36.5

363

30.5

31.1 31.8

282

24.1

24.8 25.5

201

18.5

19.1 19.8

132

13.5

14.0 14.5

78

10.2

10.6 11.0

42

7.6

7.8

8.0

24

6.3

6.4

6.5

æ I 2 + I1 ö æ Q2 + Q1 ö Dt - ç S2 – S1 = ç (8.15) ÷ ÷ Dt è 2 ø è 2 ø From Eqs (8.14) and (8.15), Q2 is evaluated as Q2 = C0 I2 + C1 I1 + C2 Q1 (8.16) - Kx + 0.5 D t (8.16a) where C0 = K - Kx + 0.5 D t Kx + 0.5 D t C1 = (8.16b) K - Kx + 0.5 D t K - Kx - 0.5 D t C2 = (8.16c) K - Kx + 0.5 D t Note that C0 + C1 + C2 = 1.0, Eq. (8.16) can be written in a general form for the nth time step as Qn = C0 In + C1 In–1 + C2 Qn–1 (8.16A)

Flood Routing

295

Equation (8.16) is known as Muskingum Routing Equation and provides a simple linear equation for channel routing. It has been found that for best results the routing interval Dt should be so chosen that K > Dt > 2Kx. If Dt < 2Kx, the coefficient C0 will be negative. Generally, negative values of coefficients are avoided by choosing appropriate values of Dt. To use the Muskingum equation to route a given inflow hydrograph through a reach, the values of K and x for the reach and the value of the outflow, Q1, from the reach at the start are needed. The procedure is indeed simple. l Knowing K and x, select an appropriate value of Dt l Calculate C0, C1 and C2. l Starting from the initial conditions I1, Q1 and known I2 at the end of the first time step Dt calculate Q2 by Eq. (8.16). l The outflow calculated in step (c) becomes the known initial outflow for the next time step. Repeat the calculations for the entire inflow hydrograph. The calculations are best done row by row in a tabular form. Example 8.5 illustrates the computation procedure. Spread sheet (such as MS Excel) is ideally suited to perform the routing calculations and to view the inflow and outflow hydrographs. EXAMPLE 8.5 Route the following flood hydrograph through a river reach for which K = 12.0 h and x = 0.20. At the start of the inflow flood, the outflow discharge is 10 m3/s. Time (h) Inflow (m3/s)

0 10

6 20

12 50

18 60

24 55

30 45

36 35

42 27

48 20

54 15

SOLUTION: Since K = 12 h and 2 Kx = 2 ´ 12 ´ 0.2 = 4.8 h, Dt should be such that 12 h > Dt > 4.8 h. In the present case Dt = 6 h is selected to suit the given inflow hydrograph ordinate interval. Using Eqs. (8. 16-a, b & c) the coefficients C0, C1 and C2 are calculated as -12 ´ 0.20 + 0.5 ´ 6 0.6 = = 0.048 C0 = 12 - 12 ´ 0.2 + 0.5 ´ 6 12.6 12 ´ 0.2 + 0.5 ´ 6 = 0.429 C1 = 12.6 12 - 12 ´ 0.2 - 0.5 ´ 6 = 0.523 C2 = 12.6 For the first time interval, 0 to 6 h, I1 = 10.0 C1I1 = 4.29

From Eq. (8.16)

I2 = 20.0

C0I2 = 0.96

Q1 = 10.0

C2Q1 = 5.23

Q2 = C0I2 + C1I1 + C2Q1

= 10.48 m3/s

For the next time step, 6 to 12 h, Q1 = 10.48 m3/s. The procedure is repeated for the entire duration of the inflow hydrograph. The computations are done in a tabular form as shown in Table 8.4. By plotting the inflow and outflow hydrographs the attenuation and peak lag are found to be 10 m3/s and 12 h respectively.

Alternative Form of Eq. (8. 16): Equations (8.14) and (8.15) can be combined in an alternative form of the routing equation as (8.17) Q2 = Q1 + B1 (I1 – Q1) + B2(I2 – I1)

296 Engineering Hydrology Table 8.4 Muskingum Method of Routing—Example 8.5 Dt = 6 h 3

Time (h)

I (m /s)

0.048 I2

0.429 I1

0.523 Q1

Q (m3/s)

1

2

3

4

5

6

10

6

20

0.96

4.29

5.23

12

50

2.40

8.58

5.48

18

60

2.88

21.45

8.61

24

55

2.64

25.74

17.23

30

45

2.16

23.60

23.85

36

35

1.68

19.30

25.95

42

27

1.30

15.02

24.55

48

20

0.96

11.58

21.38

54

15

0.72

8.58

17.74

10.00 10.48 16.46 32.94 45.61 49.61 46.93 40.87 33.92 27.04

Dt 0.5 D t - Kx B2 = K (1 - x ) + 0.5 D t K (1 - x ) + 0.5 D t The use of Eq. (8.17) is essentially the same as that of Eq. (8.16).

where

B1 =

8.6 HYDRAULIC METHOD OF FLOOD ROUTING The hydraulic method of flood routing is essentially a solution of the basic St Venant equations [Eqs (8.4) and (8.5)]. These equations are simultaneous, quasilinear, first order partial differential equations of the hyperbolic type and are not amenable to general analytical solutions. Only for highly simplified cases can one obtain the analytical solution of these equations. The development of modern, highspeed digital computers during the past two decades has given rise to the evolution of many sophisticated numerical techniques. The various numerical methods for solving St Venant equations can be broadly classified into two categories: 1. Approximate methods 2. Complete numerical methods.

Approximate Methods These are based on the equation of continuity only or on a drastically curtailed equation of motion. The hydrological method of storage routing and Muskingum channel routing discussed earlier belong to this category. Other methods in this category are diffusion analogy and kinematic wave models.

Flood Routing

297

Complete Numerical Methods These are the essence of the hydraulic method of routing and are classified into many categories as mentioned below: Complete Numerical Method

Direct Method

I

Method of Characteristics (MOC)

Finite Element method (FEM)

E Characteristic Nodes

I

C

Rectangular Grid

I

E

I = Implicit method, E = Explicit method In the direct method, the partial derivatives are replaced by finite differences and the resulting algebraic equations are then solved. In the method of characteristics (MOC) St Venant equations are converted into a pair of ordinary differential equations (i.e. characteristic forms) and then solved by finite difference techniques. In the finite element method (FEM) the system is divided into a number of elements and partial differential equations are integrated at the nodal points of the elements. The numerical schemes are further classified into explicit and implicit methods. In the explicit method the algebraic equations are linear and the dependent variables are extracted explicitly at the end of each time step. In the implicit method the dependent variables occur implicitly and the equations are nonlinear. Each of these two methods have a host of finite-differencing schemes to choose from. Details of hydraulic flood routing and a bibliography of relevant literature are available in Refs. 6, 8 and 9.

8.7

ROUTING IN CONCEPTUAL HYDROGRAPH DEVELOPMENT

Even though the routing of floods through a reservoir or channel discussed in the previous section were developed for field use, they have found another important use in the conceptual studies of hydrographs. The routing through a reservoir which gives attenuation and channel routing which gives translation to an input hydrograph are treated as two basic modifying operators. The following two fictitious items are used in the studies for development of synthetic hydrographs through conceptual models 1. Linear reservoir: a reservoir in which the storage is directly proportional to the discharge (S = KQ). This element is used to provide attenuation to a flood wave. 2. Linear channel: a fictitious channel in which the time required to translate a discharge Q through a given reach is constant. An inflow hydrograph passes through such a channel with only translation and no attenuation. Conceptual modelling for IUH development has undergone rapid progress since the first work by Zoch (1937). Detailed reviews of various contributions to this field are available in Refs. 2 and 4 and the details are beyond the scope of this book. However,

298 Engineering Hydrology a simple method, viz., Clark’s method (1945) which utilizes the Muskingum method of routing through a linear reservoir is indicated below as a typical example of the use of routing in conceptual models. Nash’s model which uses routing through a cascade of linear reservoirs is also presented, in Sec. 8.9, as another example of a conceptual model.

8.8 CLARK’S METHOD FOR IUH Clark’s method, also known as Time–area histogram method aims at developing an IUH due to an instantaneous rainfall excess over a catchment. It is assumed that the rainfall excess first undergoes pure translation and then attenuation. The translation is achieved by a travel time–area histogram and the attenuation by routing the results of the above through a linear reservoir at the catchment outlet.

Time–Area Curve Time here refers to the time of concentration. As defined earlier in Sec. 7.2, the time of concentration tc is the time required for a unit volume of water from the farthest point of catchment to reach the outlet. It represents the maximum time of translation of the surface runoff of the catchment. In gauged areas the time interval between the end of the rainfall excess and the point of inflection of the resulting surface runoff (Fig. 8.10) provides a good way of estimating tc from Fig. 8.10 Surface Runoff of a Catchment known rainfall- runoff data. In ungauged areas the empirical formulae Eq. (7.3) or (7.4) can be used to estimate tc. The total catchment area drains into the outlet in t c hours. If points on the area having equal time of travel, (say t1 h where t1 < tc), are considered and located on a map of the catchment, a line joining them is called an lsochrone (or runoff isochrone). Figure (8.11) shows a catchment being divided into Fig. 8.11 Isochrones in a Catchment N (= 8) subareas by isochrones having an equal time interval. To assist in drawing isochrones, the longest water course is chosen and its profile plotted as elevation vs distance from the outlet; the distance is

Flood Routing

299

then divided into N parts and the elevations of the subparts measured on the profile transferred to the contour map of the catchment. The inter-isochrone areas A1, A2, …, AN are used to construct a travel time-area histogram (Fig. 8.12). If a rainfall excess of 1 cm occurs instantaneously and uniformly over the catchment area, this time-area histogram represents the sequence in which the volume of rainfall will be moved out of the catchment and arrive at the outlet. In Fig. 8.12, a subarea Ar km2 represent a volume of Ar km2. cm = Ar ´ 104 (m3) moving out in time Dtc = tc/N hours. The hydrograph of outflow obtained by Fig. 8.12 Time-area Histogram this figure while properly accounting for the sequence of arrival of flows, do not provide for the storage properties of the catchment. To overcome this deficiency, Clark assumed a linear reservoir to be hypothetically available at the outlet to provide the requisite attenuation.

Routing The linear reservoir at the outlet is assumed to be described by S = KQ, where K is the storage time constant. The value of K can be estimated by considering the point of inflection Pi of a surface runoff hydrograph (Fig. 8.10). At this point the inflow into the channel has ceased and beyond this point the flow is entirely due to withdrawal from the channel storage. The continuity equation dS I–Q= dt dQ dS =K becomes –Q = (by Eq. 8.13) dt dt Hence K = –Qi /(dQ/dt)i (8. 18) where suffix i refers to the point of inflection, and K can be estimated from a known surface runoff hydrograph of the catchment as shown in Fig. 8.10. The constant K can also be estimated from the data on the recession limb of a hydrograph (Sec. 6.3). Knowing K of the linear reservoir, the inflows at various times are routed by the Muskingum method. Note that since a linear reservoir is used x = 0 in Eq. (8.12). The inflow rate between an inter-isochrone area Ar km2 with a time interval Dtc (h) is Ar Ar ´ 104 = 2.78 (m3/s) I= D tc 3600 D tc The Muskingum routing equation would now be by Eq. (8.16), (8.19) Q2 = C0 I2 + C1 I1 + C2 Q1 where C0 = (0.5 Dtc)/(K + 0.5 Dtc) C1 = (0.5 Dtc)/(K + 0.5 Dtc) C2 = (K – 0.5 Dtc)/(K + 0.5 Dtc)

300 Engineering Hydrology i.e. C0 = C1. Also since the inflows are derived from the histogram I1 = I2 for each interval. Thus Eq. (8.19) becomes Q2 = 2 C1I1 + C2Q1

(8.20)

Routing of the time-area histogram by Eq. (8.20) gives the ordinates of IUH for the catchment. Using this IUH any other D-h unit hydrograph can be derived. EXAMPLE 8.6 A drainage basin has the following characteristics: Area = 110 km2, time of concentration = 18 h, storage constant = 12 h and inter-isochrone area distribution as below: Travel time t (h) Inter-Isochrone area (km2)

0–2

2–4

4–6

6–8

8–10

3

9

20

22

16

10–12 12–14 14–16 16–18 18

10

8

4

Determine the IUH for this catchment.

SOLUTION:

K = 12 h, tc = 18 h, 0.5 ´ 2 = 0.077 C1 = 12 + 0.5 ´ 2 C2 =

Dtc = 2 h

12 - 0.5 ´ 2

= 0.846 12 + 0.5 ´ 2 Equation (8.20) becomes Q2 = 0.154I1 + 0.846 Q1 = Ordinate of IUH At

t = 0,

Q1 = 0

I1 = 2.78 Ar /2 = 1.39 Ar m3/s The calculations are shown in Table 8.5.

Table 8.5 Calculations of IUH—Clark’s Method—Example 8.6 Time (h)

Area Ar (km2)

I (m3/s)

0.154 I1

0.846 Q1

Ordinate of IUH (m3/s)

1

2

3

4

5

6

0 2 4 6 8 10 12 14 16 18 20 22

0 3 9 20 22 16 18 10 8 4 0

0 4.17 12.51 27.80 30.58 22.24 25.02 13.90 11.12 5.56 0

0 0.64 1.93 4.28 4.71 3.42 3.85 2.14 1.71 0.86 0

0 0 0.54 2.09 5.39 8.54 10.12 11.82 11.81 11.44 10.40 8.80

0 0.64 2.47 6.37 10.10 11.96 13.97 13.96 13.52 12.30 10.40 8.80 (Contd.)

Flood Routing

(Contd.) 24 26 28

7.45 6.30 5.30 M so on

301

7.45 6.30 5.30 M so on

8.9 NASH’S CONCEPTUAL MODEL Nash7 (1957) proposed the following conceptual model of a catchment to develop an equation for IUH. The catchment is assumed to be made up of a series of n identical linear reservoirs each having the same storage constant K. The first reservoir receives a unit volume equal to 1 cm of effective rain from the catchment instantaneously. This inflow is routed through the first reservoir to get the outflow hydrograph. The outflow from the first reservoir is considered as the input to the second; the outflow from the second reservoir is the input to the third and so on for all the n reservoirs. The conceptual cascade of reservoirs as above and the shape of the outflow hydrographs from each reservoir of the cascade is shown in Fig. 8.13. The outflow hydrograph from the nth reservoir is taken as the IUH of the catchment.

Fig. 8.13 Nash Model: Cascade of Linear Reservoirs

dS dt dQ dS For a linear reservoir S = K Q and hence = K dt dt Substituting in Eq. (8.1) and rearranging, dQ K +Q=I dt From the equation of continuity I – Q =

(8.1) (8.21)

(8.22)

302 Engineering Hydrology and the solution of this differential equation, where Q and I are functions of time t, is 1 -t / K t / K e Q= (8.23) ò e I dt K Now for the first reservoir, the input is applied instantaneously. Hence for t > 0, I = 0. Also at t = 0, ò I dt = instantaneous volume inflow = 1 cm of effective rain. Hence for the first reservoir Eq. (8.23) becomes, Q1 =

1 -t / K e K

(8.24)

1 -t / K t / K e ò e I dt K Here I = input = Q1 given by Eq. (8.24). Thus, 1 -t / K t / K 1 -t / K 1 –t/K e Q2 = (8.25) ò e K e dt = 2 t e K K For the third reservoir in Eq. (8.23) 1 1 2 –t/K I = Q2 and Q3 is obtained as Q3 = t e (8.26) 2 K3 Similarly, for the hydrograph of outflow from the nth reservoir Qn is obtained as 1 Qn = t n – 1e– t/K (8.27) n ( n - 1)! K As the outflow from the nth reservoir was caused by 1 cm of excess rainfall falling instantaneously over the catchment Eq. (8.27) describes the IUH of the catchment. Using the notation u(t) to represent the ordinate of the IUH, Eq. (8.27) to represent the IUH of a catchment is written as 1 u (t ) = t n – 1e– t/K (8.28) ( n - 1)! K n Here, if t is in hours, u(t) will have the dimensions of cm/h; K and n are constants for the catchment to be determined by effective rainfall and flood hydrograph characteristics of the catchment. It should be remembered that Eq. (8.28) is based on a conceptual model and as such if n for a catchment happens to be a fraction, it is still alright. To enable (n – 1)! to be determined both for integer and fractional values of n, the gamma function G (n) is used to replace (n – 1) ! so that 1 (t/K)n – 1e– t/K (8.29) u (t ) = K G (n) When n is an integer, G(n) = (n – 1)! which can be evaluated easily. However, when n is not an integer, the value of G(n) is obtained from Gamma Tables10 (Table 8.6). For the second reservoir Q2 =

Table 8.6 Gamma Function G (n) n

G(n)

n

G(n)

n

G(n)

1.00 1.02 1.04

1.000000 0.988844 0.978438

1.34 1.36 1.38

0.892216 0.890185 0.888537

1.68 1.70 1.72

0.905001 0.908639 0.912581 (Contd.)

Flood Routing

(Contd.) 1.06 1.08 1.10 1.12 1.14 1.16 1.18 1.20 1.22 1.24 1.26 1.28 1.30 1.32

0.968744 0.959725 0.951351 0.943590 0.936416 0.929803 0.923728 0.918169 0.913106 0.908521 0.904397 0.900718 0.897471 0.894640

1.40 1.42 1.44 1.46 1.48 1.50 1.52 1.54 1.56 1.58 1.60 1.62 1.64 1.66

0.887264 0.886356 0.885805 0.885604 0.885747 0.886227 0.887039 0.888178 0.889639 0.891420 0.893515 0.895924 0.898642 0.901668

1.74 1.76 1.78 1.80 1.82 1.84 1.86 1.88 1.90 1.92 1.94 1.96 1.98 2.00

303

0.916826 0.921375 0.926227 0.931384 0.936845 0.942612 0.948687 0.955071 0.961766 0.968774 0.976099 0.983743 0.991708 1.000000

Note: Use the relation G(n + 1) = n G (n) to evaluate G (n) for any n. EXAMPLE: (a) To find G(0.6) : G(1.6) = G (0.6 + 1) = 0.6 G (0.6) thus G (0.6) =

G (1.6 ) 0.8935 = = 1.489 0.6 0.6

(b) To find G(4.7) : G(4.7)= G(3.7+1) = 3.7 G(3.7) = 3.7 ´ 2.7 G(2.7) = 3.7 ´ 2.7 ´ 1.7 ´ G(1.7) = 3.7 ´ 2.7 ´ 1.7 ´ 0.9086 = 15.431

Determination of n and K of Nash’s model From the property of the IUH given by Eq. (8.28), it can be shown that the first moment of the IUH about the origin t = 0 is given by M1 = nK (8.30) Also the second moment of the IUH about the origin t = 0 is given by M2 = n (n + 1) K2 (8.31) Using these properties the values of n and K for a catchment can be determined adequately if the ERH and a corresponding DRH are available. If MQ1 = first moment of the DRH about the time origin divided by the total direct runoff, and MI1 = first moment of the ERH about the time origin divided by the total effective rainfall, (8.32) then, MQ1 – MI1 = nK Further, if MQ2 = second moment of DRH about the time origin divided by total direct runoff, and MI2 = second moment of ERH about the time origin divided by total excess rainfall, then, MQ2 – MI2 = n (n + 1) K2 +2nK MI1 (8.33) Knowing MI1, MI2, MQ1 and MQ2, values of K and n for a given catchment can be calculated by Eqs. (8.32) and (8.33).

304 Engineering Hydrology Example 8.7 illustrates the method of determining n and K of the Nash’s model. Example 8.8 describes the computation of IUH and a D-hour UH when the values of n and K are known. EXAMPLE 8.7 For a catchment the effective rainfall hyetograph of an isolated storm and the corresponding direct runoff hydrograph is given below. Determine the coefficients n and K of Nash model IUH. Coordinates of ERH: Time from start of storm (h)

Effective rainfall intensity (cm/s)

0 to 1.0 1.0 to 2.0 2.0 to 3.0 3.0 to 4.0

4.3 3.2 2.4 1.8

Coordinates of DRH: Time from start of storm (h)

Direct runoff (m3/s)

Time from start of storm (h)

Direct runoff (m3/s)

0 1 2 3 4 5 6 7 8

0 6.5 15.4 43.1 58.1 68.2 63.1 52.7 41.9

9 10 11 12 13 14 15 16

32.7 23.8 16.4 9.6 6.8 3.2 1.5 0

SOLUTION: The ERH is shown in Fig. 8.14(a) as a histogram. Each block has the total rainfall in a time interval of 1 hour marked on it. MI1 = first moment of the ERH about the time origin divided by the total rainfall excess.

Fig. 8.14(a) Excess rainfall hyetograph of Example 8.7

Flood Routing

MI1 =

305

å (Incremental area of ERH ´ moment arm) total area of ERH

MI2 = second moment of the ERH about the time origin divided by the total rainfall excess.

ìå [incremental area ´ (moment arm)2 ] ü ï ï 1 = í + å [ second moment of the incremental ý total area of ERH ï ï î area about its own centroid] þ The calculations of MI 1 and MI2 are shown in Table 8.7(a)

{

}

Table 8.7(a) Calculation of MI1 and MI2 : Example 8.7 1 Time (h)

2

3

4

Excess Interval rainfall Dt in Dt (cm) (h)

0 1 2 3 4

0 4.3 3.2 2.4 1.8

0 1 1 1 1

Incre. area 0 4.3 3.2 2.4 1.8

Sum

11.7

5

6

7

8

Second moment part (a)

Second moment part (b)

0 2.15 4.8 6.0 6.3

0 1.08 7.20 15.00 22.05

0 0.358 0.267 0.200 0.150

19.25

45.325

0.975

moment First arm moment 0 0.5 1.5 2.5 3.5

In Table 8.7(a)

Col. 6 = first moment of the incremental area about the origin = (Col. 4 ´ Col. 5) Col. 7 = Col. 4 ´ (Col. 5)2 Col. 8 = second moment of the incremental area about its own centroid 1 1 = ´ (Dt)3 (ER) = ´ (Col. 3)3 ´ (Col. 2) 12 12 From the data of Table 8.7(a): MIl = (sum of Col. 6)/(sum of Col. 4) = 19.25/11.7 = 1.645 MI2 = {(sum of Col. 7) + (sum of Co1. 8)}/(sum of Col. 4) = (45.325 + 0.975)}/11.75 = 3.957 The DRH is shown plotted in Fig. 8.14(b). A time interval of Dt = 1 hour is chosen and considering the average DR in this interval the DRH is taken to be made up of large number of rectangular blocks. For the DRH MQ1 = first moment of the DRH about the time origin divided by the total direct runoff å (Incremental area of DRH ´ moment arm) = total area of DRH MQ2 = second moment of the DRH about the time origin divided by the total direct runoff

ìå [incremental area ´ (moment arm)2 ] ü ï ï 1 í + [ second moment of the incremental ý = total area of DRH ï å ï î area about its own centroid] þ The calculations of MQ1 and MQ2 are shown in Table 8.7(b).

{

}

306 Engineering Hydrology

Fig. 8.14(b) Direct runoff hydrograph of Example 8.7 Table 8.7(b) Calculation of MQ1 and MQ2—Example 8.7 1

2

3

4

5

6

7

8

9

Time Ord. of Average Interval Increment Moment First Second Second (h) DRH DR rate in Dt (h) area arm Moment Moment Moment (m3/s) Dt (m3/s) part (a) part (b) 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 Sum

0 6.5 15.4 43.1 58.1 68.2 63.1 52.7 41.9 32.7 23.8 16.4 9.6 6.8 3.2 1.5 0

0.00 3.25 10.95 29.25 50.60 63.15 65.65 57.90 47.30 37.30 28.25 20.10 13.00 8.20 5.00 2.35 0.75

0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1

0.00 3.25 10.95 29.25 50.60 63.15 65.65 57.90 47.30 37.30 28.25 20.10 13.00 8.20 5.00 2.35 0.75 443.00

0 0.5 1.5 2.5 3.5 4.5 5.5 6.5 7.5 8.5 9.5 10.5 11.5 12.5 13.5 14.5 15.5

0.00 1.63 16.43 73.13 177.10 284.18 361.08 376.35 354.75 317.05 268.38 211.05 149.50 102.50 67.50 34.08 11.63

0.00 0.81 24.64 182.81 619.85 1278.79 1985.91 2446.28 2660.63 2694.93 2549.56 2216.03 1719.25 1281.25 911.25 494.09 180.19

0.00 0.27 0.91 2.44 4.22 5.26 5.47 4.83 3.94 3.11 2.35 1.68 1.08 0.68 0.42 0.20 0.06

2806.30

21246.25

36.92

In Table 8.7(b): Col. 7 = first moment of the incremental area of DRH about the origin = (Col. 4 ´ Col. 5)

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307

Col. 8 = Col. 5 ´ (Col. 6)2 Col. 9 = second moment of the incremental area about its own centroid 1 = ´ (Col. 4)3 ´ (Col. 3) 12 From the data of Table 8.7(b): MQ1 = (sum of Col. 7)/(sum of Col. 5) = 2806.3/443 = 6.33 MQ2 = {(sum of Col. 8) + (sum of Col. 9)}/(sum of Col. 5) = (21246.25 + 36.92)/443 = 48.04 [Note that in the calculation of MI2 and MQ2, for small values of Dt the second term in the bracket, viz. second moment part (b) = S [second moment of incremental area about its own centroid], is relatively small in comparison with the first term [part(a)] and can be neglected without serious error.] By Eq. (8.30) n K = MQ1 – MI1 = 6.335 – 1.645 = 4.690 By Eq. (8.31) MQ2 – MI2 = n (n + 1) K2 + 2 n K MI1 = (nK)2 + (nK) K + 2(nK) MI1 Substituting for nK, MQ2, MI2 and MI1 48.04 – 3.96 = (4.69)2 + (4.69) K + 2 (4.69) (1.645) K = 6.654/4.69 = 1.42 hours n = nK/K = 4.69/1.42 = 3.30

EXAMPLE 8.8 For a catchment of area 300 km2 the values of the Nash model coeffi-

cients are found to have values of n = 4.5 and K = 3.3 hours. Determine the ordinates of (a) IUH and (b) 3-h unit hydrograph of the catchment.

SOLUTION: The ordinates of IUH by Nash model are given by

1 (t/K)n – 1 e(t/K) K G (n) In the present case n = 4.5, K = 3.3 hours and u(t) is in cm/h. G(n) = G(4.5) = 3.5 G(3.5) = 3.5 ´ 2.5 G(2.5) = 3.5 ´ 2.5 ´ 1.5 ´ G(1.5) From Table 8.6, G(1.5) = 0.886227 Hence G(4.5) = 3.5 ´ 2.5 ´ 1.5 ´ 0.886227 = 11.632 1 u(t) = (t/3.5)3.5 e–(t/3.3) = 0.02605 (t/3.3)3.5 e–(t/3.3) 3.3 ´ 11.632 Values of u(t) for various values of t are calculated as shown in Table 8.8. An interval of one hour is chosen. In Table 8.8, Col. 3 gives the ordinates of u(t) in cm/h. Multiplying these values by (2.78 ´ A) where A = area of the catchment in km2 gives the values of u(t) in m3/s, (Col. 4). Thus Col. 4 = (Col. 3) ´ 2.78 ´ 300 = (Col. 3) ´ 834 Col. 5 is the ordinate of u(t) [i.e. Col. 4] lagged by one hour Col. 6 = (Col. 4 + Co1. 6)/2 = ordinate of 1-h UH by Eq. (6.26) The S-curve technique is used to derive the 3-h UH from the 1-h UH obtained in Col. 6. Col. 7 = S1–curve addition. Col. 8 = S1–curve ordinates Col. 9 = S1–curve ordinates lagged by 3 hours Col. 10 = (Col. 8 – Col. 9) = ordinates of a DRH of 3 cm occurring in 3 hours. Col. 11 = (Col. 10)/3 = ordinates of 3-h UH

u(t) =

308 Engineering Hydrology Table 8.8 Calculation of 3-Hour UH by Nash Method—Example 8.8 K = 3.3 h 1

2

Time (t/K) t in hours 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40

0.000 0.303 0.606 0.909 1.212 1.515 1.818 2.121 2.424 2.727 3.030 3.333 3.636 3.939 4.242 4.545 4.848 5.152 5.455 5.758 6.061 6.364 6.667 6.970 7.273 7.576 7.879 8.182 8.485 8.788 9.091 9.394 9.697 10.000 10.303 10.606 10.909 11.212 11.515 11.818 12.121

n = 4.5 3

Area of the catchment = 300 km2

G(n) = 11.632 4

5

6

7

8

9

10

11

u(t) (cm/h)

DRH of Ord. u(t) u(t) 1-h S1– Ordinate 3-h Curve of S1- lagged 3 cm in of 3-h (m3/s) lagged UH S13 hours UH by 1 (m3/s) addition Curve hour Curve (m3/s) (m3/s)

0.0000 0.0003 0.0025 0.0075 0.0152 0.0245 0.0343 0.0434 0.0512 0.0571 0.0610 0.0628 0.0629 0.0615 0.0589 0.0554 0.0513 0.0468 0.0422 0.0377 0.0333 0.0292 0.0254 0.0219 0.0188 0.0160 0.0135 0.0114 0.0096 0.0080 0.0067 0.0055 0.0045 0.0037 0.0031 0.0025 0.0020 0.0017 0.0013 0.0011 0.0009

0.000 0.246 2.054 6.271 12.676 20.444 28.583 36.209 42.676 47.600 50.834 52.411 52.490 51.303 49.112 46.180 42.751 39.039 35.219 31.431 27.779 24.337 21.153 18.253 15.647 13.332 11.295 9.520 7.986 6.669 5.546 4.594 3.792 3.119 2.558 2.091 1.704 1.385 1.123 0.909 0.733

0.000 0.246 2.054 6.271 12.676 20.444 28.583 36.209 42.676 47.600 50.834 52.411 52.490 51.303 49.112 46.180 42.751 39.039 35.219 31.431 27.779 24.337 21.153 18.253 15.647 13.332 11.295 9.520 7.986 6.669 5.546 4.594 3.792 3.119 2.558 2.091 1.704 1.385 1.123 0.909

0.000 0.123 1.150 4.162 9.473 16.560 24.513 32.396 39.442 45.138 49.217 51.623 52.451 51.897 50.207 47.646 44.466 40.895 37.129 33.325 29.605 26.058 22.745 19.703 16.950 14.489 12.313 10.408 8.753 7.328 6.108 5.070 4.193 3.456 2.838 2.324 1.897 1.545 1.254 1.016 0.821

0.000 0.000 0.123 1.273 5.435 14.909 31.469 55.982 88.378 127.820 172.958 222.175 273.798 326.248 378.145 428.353 475.998 520.464 561.359 598.488 631.812 661.417 687.475 710.221 729.924 746.875 761.364 773.677 784.085 792.838 800.166 806.273 811.344 815.537 818.992 821.831 824.155 826.052 827.597 828.851 829.867

0.000 0.123 1.273 5.435 14.909 31.469 55.982 88.378 127.820 172.958 222.175 273.798 326.248 378.145 428.353 475.998 520.464 561.359 598.488 631.812 661.417 687.475 710.221 729.924 746.875 761.364 773.677 784.085 792.838 800.166 806.273 811.344 815.537 818.992 821.831 824.155 826.052 827.597 828.851 829.867 830.688

0.000 0.123 1.273 5.435 14.909 31.469 55.982 88.378 127.820 172.958 222.175 273.798 326.248 378.145 428.353 475.998 520.464 561.359 598.488 631.812 661.417 687.475 710.221 729.924 746.875 761.364 773.677 784.085 792.838 800.166 806.273 811.344 815.537 818.992 821.831 824.155 826.052 827.597

0.000 0.123 1.273 5.435 14.786 30.196 50.547 73.469 96.351 116.975 133.797 145.978 153.291 155.970 154.555 149.750 142.319 133.006 122.489 111.348 100.058 88.988 78.408 68.507 59.399 51.143 43.753 37.210 31.474 26.488 22.188 18.505 15.371 12.719 10.487 8.618 7.060 5.766 4.696 3.815 3.091

0.00 0.40 0.42 1.81 4.93 10.07 16.85 24.49 32.12 38.99 44.60 48.66 51.10 51.99 51.52 49.92 47.44 44.34 40.83 37.12 33.35 29.66 26.14 22.84 19.80 17.05 14.58 12.40 10.49 8.83 7.40 6.17 5.12 4.24 3.50 2.87 2.35 1.92 1.57 1.27 1.03

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8.10 FLOOD CONTROL The term flood control is commonly used to denote all the measures adopted to reduce damages to life and property by floods. Currently, many people prefer to use the term flood management instead of flood control as it reflects the activity more realistically. As there is always a possibility, however remote it may be, of an extremely large flood occurring in a river the complete control of the flood to a level of zero loss is neither physically possible nor economically feasible. The flood control measures that are in use can be classified as: 1. Structural measures: l Storage and detention reservoirs l Levees (flood embankments)

Flood ways (new channels) Watershed management 2. Non-structural methods: l Flood plain zoning l Evacuation and relocation l

l

Channel improvement

l

Flood forecast/warning Flood insurance

l

l

Structural Methods Storage Reservoirs Storage reservoirs offer one of the most reliable and effective methods of flood control. Ideally, in this method, a part of the storage in the reservoir is kept apart to absorb the incoming flood. Further, the stored water is released in a controlled way over an extended time so that downstream channels do not get flooded. Figure 8.15 shows an ideal operating plan of a flood control reservoir. As most of the present-day storage reservoirs have multipurpose commitments, the manipulation of reservoir levels to satisfy many conflicting demands is a very difficult and complicated task. It so happens that many storage reservoirs while reducing the floods and flood damages do not always aim at achieving optimum benefits in the flood-control aspect. To achieve complete flood control in the entire length of the river, a large number of reservoirs at strategic locations in the catchment will be necessary.

Fig. 8.15 Flood control operation of a reservoir The Hirakud and Damodar Valley Corporation (DVC) reservoirs are examples of major reservoirs in the country which have specific volumes earmarked for flood absorption.

310 Engineering Hydrology Detention Reservoirs A detention reservoir consists of an obstruction to a river with an uncontrolled outlet. These are essentially small structures and operate to reduce the flood peak by providing temporary storage and by restriction of the outflow rate. These structures are not common in India. Levees Levees, also known as dikes or flood embankments are earthen banks constructed parallel to the course of the river to confine it to a fixed course and limited cross-sectional width. The heights of levees will be higher than the design flood level with sufficient free board. The confinement of the river to a fixed path frees large tracts of land from inundation and consequent damage (Fig. 8.16).

Fig. 8.16 A typical levee: (a) Plan (schematic), (b) Cross-section Levees are one of the oldest and most common methods of flood-protection works adopted in the world. Also, they are probably the cheapest of structural flood-control measures. While the protection offered by a levee against food damage is obvious, what is not often appreciated is the potential damage in the event of a levee failure. The levees, being earth embankments require considerable care and maintenance. In the event of being overtopped, they fail and the damage caused can be enormous. In fact, the sense of protection offered by a levee encourages economic activity along the embankment and if the levee is overtopped the loss would be more than what would have been if there were no levees. Confinement of flood banks of a river by levees to a narrower space leads to higher flood levels for a given discharge. Further, if the bed levels of the river also rise, as they do in aggrading rivers, the top of the levees have to be raised at frequent time intervals to keep up its safety margin. The design of a levee is a major task in which costs and economic benefits have to be considered. The cross-section of a levee will have to be designed like an earth dam

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311

for complete safety against all kinds of saturation and drawdown possibilities. In many instances, especially in locations where important structures and industries are to be protected, the water side face of levees are protected by stone or concrete revetment. Regular maintenance and contingency arrangements to fight floods are absolutely necessary to keep the levees functional. Masonry structures used to confine the river in a manner similar to levees are known as flood walls. These are used to protect important structures against floods, especially where the land is at a premium. Floodways Floodways are natural channels into which a part of the flood will be diverted during high stages. A floodway can be a natural or man-made channel and its location is controlled essentially by the topography. Generally, wherever they are feasible, floodways offer an economical alternative to other structural flood-control measures. To reduce the level of the river Jhelum at Srinagar, a supplementary channel has been constructed to act as a floodway with a capacity of 300 m3/s. This channel is located 5 km upstream of Srinagar city and has its outfall in lake Wullar. In Andhra Pradesh, a floodway has been constructed to transfer a part of the flood waters of the river Budamaru to river Krishna to prevent flood damages to the urban areas lying on the downstream reaches of the river Budamaru. Channel Improvement The works under this category involve: l Widening or deepening of the channel to increase the cross-sectional area l Reduction of the channel roughness, by clearing of vegetation from the channel perimeter l Short circuiting of meander loops by cutoff channels, leading to increased slopes. All these three methods are essentially short-term measures and require continued maintenance. Watershed Management Watershed management and land treatment in the catchment aims at cutting down and delaying the runoff before it gets into the river. Watershed management measures include developing the vegetative and soil cover in conjunction with land treatment words like Nalabunds, check dams, contour bunding, zing terraces etc. These measures are towards improvement of water infiltration capacity of the soil and reduction of soil erosion. These treatments cause increased infiltration, greater evapotranspiration and reduction in soil erosion; all leading to moderation of the peak flows and increasing of dry weather flows. Watershed treatment is nowadays an integral part of flood management. It is believed that while small and medium floods are reduced by watershed management measures, the magnitude of extreme floods are unlikely to be affected by these measures.

Non-Structural Methods The flood management strategy has to include the philosophy of Living with the floods. The following non-structural measures encompass this aspect. Flood Plain Zoning When the river discharges are very high, it is to be expected that the river will overflow its banks and spill into flood plains. In view of the increasing pressure of population this basic aspects of the river are disregarded and there are greater encroachment of flood plains by man leading to distress. Flood plain management identifies the flood prone areas of a river and regulates the land use to restrict the damage due to floods. The locations and extent of areas

312 Engineering Hydrology Zone

Flood Return Period

Example of Uses

1

100 Years

Residential houses, Offices, Factories, etc.

2

25 Years

Parks

3

Frequent

No construction/Encroachments

Fig. 8.17 Conceptual Zoning of a Flood Plain likely to be affected by floods of different return periods are identified and development plans of these areas are prepared in such a manner that the resulting damages due to floods are within acceptable limits of risk. Figure 8.17 shows a conceptual zoning of a flood prone area. Flood Forecasting and Warning Forecasting of floods sufficiently in advance enables a warning to be given to the people likely to be affected and further enables civil authorities to take appropriate precautionary measures. It thus forms a very important and relatively inexpensive non-structural flood management measure. However, it must be realised that a flood warning is meaningful only if it is given sufficiently in advance. Further, erroneous warnings will cause the populace to lose confidence and faith in the system. Thus the dual requirements of reliability and advance notice are the essential ingredients of a flood-forecasting system. The flood forecasting techniques can be broadly divided into three categories: (i) Short range forecasts (ii) Medium range forecasts (iii) Long range forecasts. Short-Range Forecasts In this the river stages at successive stations on a river are correlated with hydrological parameters, such as rainfall over the local area, antecedent precipitation index, and variation of the stage at the upstream base point during the travel time of a flood. This method can give advance warning of 12-40 hours for floods. The flood forecasting used for the metropolitan city of Delhi is based on this technique. Medium-Range Forecasts In this method rainfall–runoff relationships are used to predict flood levels with warning of 2–5 days. Coaxial graphical correlations of runoff, with rainfall and other parameters like the time of the year, storm duration and antecedent wetness have been developed to a high stage of refinement by the US Weather Bureau.

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313

Long-Range Forecasts Using radars and meteorological satellite data, advance information about critical storm-producing weather systems, their rain potential and time of occurrence of the event are predicted well in advance. Evacuation and Relocation Evacuation of communities along with their live stocks and other valuables in the chronic flood affected areas and relocation of them in nearby safer locations is an area specific measure of flood management. This would be considered as non-structural measure when this activity is a temporary measure confined to high floods. However, permanent shifting of communities to safer locations would be termed as structural measure. Raising the elevations of buildings and public utility installations above normal flood levels is termed as flood proofing and is sometimes adopted in coastal areas subjected to severe cyclones. Flood Insurance Flood insurance provides a mechanism for spreading the loss over large numbers of individuals and thus modifies the impact of loss burden. Further, it helps, though indirectly, flood plain zoning, flood forecasting and disaster preparedness activities.

8.11 FLOOD CONTROL IN INDIA In India the Himalayan rivers account for nearly 60% of the flood damage in the country. Floods in these rivers occur during monsoon months and usually in the months of August or September. The damages caused by floods are very difficult to estimate and a figure of Rs 5000 crores as the annual flood damage in the country gives the right order of magnitude. During 1953–2000, the average number of human lives and cattle lost due to floods in the country were 1595 and 94,000 respectively. It is estimated that annually, on an average about 40 M ha of land is liable to flooding and of this about 14 M ha have some kind of flood-control measure. At the beginning of the current millennium, in the country, as a part of flood control measure there were about 15800 km of levees and about 32000 km of drainage channels affording protection from floods. On an average about 7.5 M ha land is affected by floods annually. Out of this, about 3.5 M ha are lands under crops. Similarly, annually about 3.345 lakhs of people are affected and about 12.15 lakhs houses are damaged by floods. On an average, about 60 to 80% of flood damages occur in the states of U.P., Bihar, West Bengal, Assam and Orissa. Flood forecasting is handled by CWC in close collaboration with the IMD which lends meteorological data support. Nine flood Met offices with the aid of recording raingauges provide daily synoptic situations, actual rainfall amounts and rainfall forecasts to CWC. The CWC has 157 flood-forecasting stations, of which 132 stations are for river stage forecast and 25 for inflow forecast, situated in various basins to provide a forecasting service. A national program for flood management was launched in 1954 and an amount of 3165 crores was spent till 1992. The ninth plan (1997–2002) had an outlay of 2928 crores for flood management. These figures highlight the seriousness of the flood problem and the efforts made towards mitigating flood damages. The experience gained in the flood control measures in the country are embodied in the report of the Rashtriya Barh Ayog (RBA) (National Flood Commission) submitted in March 1980. This report, containing a large number of recommendations on all aspects of flood control

314 Engineering Hydrology forms the basis for the evolution of the present national policy on floods. According to the national water policy (1987), while structural flood control measures will continue to be necessary, the emphasis should be on non-structural methods so as to reduce the recurring expenditure on flood relief.

REFERENCES 1. Butler, S.S., “Point slope approach for reservoir flood routing”, J. of Hyd. Div., Proc. ASCE, Oct. 1982, pp 1102–1113. 2. Chow, V.T., Handbook of Applied Hydrology, McGraw-Hill, New York, NY, 1964. 3. Chow, V.T., Maidment, D.R. and Mays, L.W., Applied Hydrology, McGraw-Hill Book Co., Singapore, 1988. 4. Kraijenhoff Van der lam, D.A., “Rainfall-runoff relations and computational model”, Ch. 15 in Drainage Principles and Applications, Vol. II, Pub. No. 16, Int. Inst. for Land Reclamation and Improvement, Wageningen, The Netherlands, 1973. 5. Linsley, R.K. et al., Applied Hydrology, Tata McGraw-Hill, New Delhi, India, 1975. 6. Mahmood, K. and Yevjevich V. (Ed.) Unsteady Flow in Open Channels, Vols.1 and 2, Water Resources Pub., Fort Collins, Colo, USA, 1975. 7. Nash, J.E., “The form of instantaneous unit hydrograph”, IASH, Pub. No. 45, Vol. 3–4, pp 114–121,1957. 8. Streeter, V.L. and Wylie, E.B., Hydraulic Transients, McGraw-Hill, New York, NY, 1967. 9. Subramanya, K., Flow in Open Channels, 2nd Ed. Tata McGraw-Hill, New Delhi, India, 1997. 10. Pierce, B.O. and Foster, R.M., A Short Table of Integrals, Oxford, IBH New Delhi, India, 1963.

REVISION QUESTIONS 8.1

Distinguish between: (a) Hydraulic and hydrologic method of flood routing (b) Hydrologic storage routing and hydrologic channel routing (c) Prism storage and wedge storage 8.2 What are the basic equations used for flood routing by (a) Hydrologic method, and (b) Hydraulic method 8.3 Define the problem of level pool routing. Describe a commonly used method of reservoir routing. 8.4 Describe a numerical method of hydrologic reservoir routing. 8.5 What is the basic premise in the Muskingum method of flood routing? Describe a procedure for estimating the values of the Muskingum coefficients K and x for a stream reach. 8.6 Describe the Muskingum method of routing an inflow hydrograph through a channel reach. Assume the values of the coefficients K and x for the reach are known. 8.7 Explain briefly (a) Isochrone (b) Time of concentration (c) Linear reservoir (d) Linear channel 8.8 Explain briefly the basic principles involved in the development of IUH by (a) Clark’s method, and (b) Nash’s model. 8.9 Describe the various structural methods adopted for management of floods. 8.10 Describe the various non-structural measures of flood management. 8.11 Describe the problem of floods and their management with special reference to Indian scene.

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315

PROBLEMS 8.1 The storage, elevation and outflow data of a reservoir are given below: Elevation (m)

Storage 106 m3

Outflow discharge (m3/s)

299.50 300.20 300.70 301.20 301.70 302.20 302.70

4.8 5.5 6.0 6.6 7.2 7.9 8.8

0 0 15 40 75 115 160

The spillway crest is at elevation 300.20 m. The following flood flow is expected into the reservoir. Time (h) Discharge (m3/s)

0 10

3 20

6 52

9 60

12 53

15 43

18 32

21 22

24 16

27 10

If the reservoir surface is at elevation 300.00 m at the commencement of the inflow, route the flood to obtain (a) the outflow hydrograph and (b) the reservoir elevation vs time curve. 8.2 Solve Prob. 8.1 if the reservoir elevation at the start of the inflow hydrograph is at 301.50 m. 8.3 A small reservoir has the following storage elevation relationship. Elevation (m) Storage (103 m3)

55.00 250

58.00 650

60.00 1000

61.00 1250

62.00 1500

63.00 1800

A spillway provided with its crest at elevation 60.00 m has the discharge relationship Q = 15 H3/2, where H = head of water over the spillway crest. When the reservoir elevation is at 58.00 m a flood as given below enters the reservoir. Route the flood and determine the maximum reservoir elevation, peak outflow and attenuation of the flood peak. Time (h) Inflow (m3/s)

0 5

6 20

12 40

15 60

18 50

24 32

30 22

36 15

42 10

8.4 The storage-elevation-discharge characteristic of a reservoir is as follows: Elevation (m) Discharge (m3/s) Storage (103 m3)

100.00 12 400

100.50 18 450

101.00 25 550

When the reservoir elevation is at 101.00 m the inflow is at a constant rate of 10 m3/s. Find the time taken for the water surface to drop to the elevation 100.00 m. 8.5 A small reservoir has a spillway crest at elevation 200.00 m. Above this elevation, the storage and outflow from the reservoir can be expressed as Storage: S = 36000 + 18000 y (m3) Outflow: Q = 10 y (m3/s) where y = height of the reservoir level above the spillway crest in m. Route an inflow flood hydrograph which can be approximated by a triangle as I = 0 at t = 0 h I = 30 m3/s at t = 6 h (peak flow) I = 0 at t = 26 h (end of inflow). Assume the reservoir elevation as 200.00 m at t = 0 h. Use a time step of 2 h.

316 Engineering Hydrology 8.6

A detention reservoir was found to have a linear storage discharge relationship, Q = KQ (a) Show that the storage routing equation of an inflow hydrograph through this reservoir is Q2 = C1 I1 + C2Q2 where C1 and C2 are constants and I1 = (I1 + I2)/ 2. Determine the values of C1 and C2 in terms of K and the routing time step Dt. (b) If K = 4.0 h and Dt = 2 h, route the following inflow hydrograph through this reservoir. Assume the initial condition that at t = 0, I1 = Q1 = 0. Time (h) Inflow (m3/s)

8.7

2 20

4 60

6 100

8 80

10 60

12 40

14 30

16 20

18 10

Observed values of inflow and outflow hydrographs at the ends of a reach in a river are given below. Determine the best values of K and x for use in the Muskingum method of flood routing. Time (h) Inflow (m3/s) Outflow (m3/s)

8.8

0 0

0 20 20

6 12 18 24 30 36 42 48 80 210 240 215 170 130 90 60 20 50 150 200 210 185 155 120

54 60 40 28 85 55

66 16 23

Route the following flood through a reach for which K = 22 h and x = 0.25. Plot the inflow and outflow hydrographs and determine the peak lag and attenuation. At t = 0 the outflow discharge is 40 m3/s. Time (h) 0 12 24 36 48 60 72 84 96 108 120 132 144 Inflow (m3/s) 40 65 165 250 240 205 170 130 115 85 70 60 54

8.9

The storage in the reach of a stream has been studied. The values of x and K in Muskingum equation have been identified as 0.28 and 1.6 days. If the inflow hydrograph to the reach is as given below, compute the outflow hydrograph. Assume the outflow from the reach at t = 0 as 3.5 m3/s. Time (h) Inflow (m3/s)

0 35

6 55

12 92

18 130

24 160

30 140

8.10 Route the following flood hydrograph through a river reach for which Muskingum coefficient K = 8 h and x = 0.25. Time (h) Inflow (m3/s)

0 8

4 16

8 30

12 30

16 25

20 20

24 15

28 10

The initial outflow discharge from the reach is 8.0 m3/s. 8.11 A stream has a uniform flow of 10 m3/s. A flood in which the discharge increases linearly from 10 m3/s to a peak of 70 m3/s in 6 h and then decreases linearly to a value of 10 m3/s in 24 h from the peak arrives at a reach. Route the flood through the reach in which K = 10 h and x = 0 8.12 A drainage basin has area = 137 km2, storage constant K = 9.5 h and time of concentration = 7 h. The following inter-isochrone area distribution data are available: Time (h) Inter-isochrone area (km2)

0–1 10

1–2 38

2–3 20

3–4 45

4–5 32

Determine (a) the IUH and (b) the 1-h unit hydrograph for the catchment.

5–6 10

6–7 2

Flood Routing

317

8.13 Solve Prob. 8.11 K = 10 h and x = 0.5. Determine the peak lag and attenuation and compare with the corresponding values of Prob. 8.11. 8.14 Show that the reservoir routing equation for a linear reservoir is

dQ dt

+ =Q = =I

where = is a constant. Obtain the outflow from such a reservoir due to an inflow I = I0 + > t occurring from t = 0 to t0 with the boundary condition Q = 0 at t = 0. 8.15 Given that n = 4.0 and K = 6.0 are the appropriate values of the coefficients in the Nash model for IUH of a catchment, determine the ordinates of IUH in cm/h at 3 hours interval. If the catchment area is 500 km2, determine the ordinates of the IUH in m3/s. 8.16 Show that in the IUH obtained by using the Nash model the peak flow occurs at a time tp = K (n – 1) and the magnitude of the peak flow is u(t)p =

1 e(1–n) (n – 1)n–1 K G (n)

8.17 For a sub-basin in lower Godavari catchment, with an area of 250 km2 the following values of Nash model coefficients were found appropriate: n = 3.3 and K = 1.69 h. Determine the co-ordinates of (a) IUH at 1-h interval and (b) 1-hour UH at 1-h interval. 8.18 For a catchment X of area 100 km2, an ERH of an isolated storm and its corresponding DRH were analysed to determine the first and second moments relative to the total area of the respective curves and the following values were obtained: (1) (First moment of the curve)/(total area of the curve): ERH = 11.0 h DRH = 25.0 h (2) (Second moment of the curve)/(total area of the curve): ERH = 170 h2 DRH = 730 h2 Determine the IUH with ordinates at 2 hour interval for catchment X by using Nash model. 8.19 For a catchment the effective rainfall hyetograph due to an isolated storm is given in Table 8.9(a). The direct runoff hydrograph resulting from the above storm is given in Table 8.9(b). Determine the values of Nash model IUH coefficients n and K for the above catchment.

Table 8.9(a) ERH Time (h) ERH ordinates (cm/s)

0 to 6 4.3

6 to 12 2.8

12 to 18 3.9

18 to 24 2.7

Table 8.9(b) DRH Time (h)

DR m3/s

Time (h)

0 6 12 18 24 30

0 20 140 368 380 280

36 42 48 54 60

DR m3/s 160 75 30 10 0

318 Engineering Hydrology

OBJECTIVE QUESTIONS 8.1 8.2

8.3

8.4 8.5 8.6

8.7

The hydrologic flood-routing methods use (a) Equation of continuity only (b) Both momentum and continuity equations (c) Energy equation only (d) Equation of motion only The hydraulic methods of flood routing use (a) Equation of continuity only (b) Both the equation of motion and equation of continuity (c) Energy equation only (b) Equation of motion only The St Venant equations for unsteady open-channel flow are (a) continuity and momentum equations (b) momentum equation in two different forms (c) momentum and energy equations (d) energy and continuity equations. The prism storage in a river reach during the passage of a flood wave is (a) a constant (b) a function of inflow and outflow (c) function of inflow only (d) function of outflow only The wedge storage in a river reach during the passage of a flood wave is (a) a constant (b) negative during rising phase (c) positive during rising phase (d) positive during falling phase In routing a flood through a reach the point of intersection of inflow and outflow hydrographs coincides with the peak of outflow hydrograph (a) in all cases of flood routing (b) when the inflow is into a reservoir with an uncontrolled outlet (c) in channel routing only (d) in all cases of reservoir routing. Which of the following is a proper reservoir-routing equation? Q1 D t ö æ Q2 D t ö æ 1 (I1 – I2) Dt + ç S1 + ÷ø = çè S2 ÷ è 2 2 2 ø æ 2 S1 ö æ 2 S2 ö - Q1 ÷ = ç + Q2 ÷ (b) (I1 + I2) Dt + ç D D è t ø è t ø

(a)

1 (I1 + I2) Dt + 2 æ 2 S1 (d) (I1 + I2) + ç è Dt

(c)

Q2 D t ö æ Q1 D t ö æ çè S2 ÷ø = çè S1 + ÷ 2 2 ø

ö æ 2 S2 ö - Q1 ÷ = ç + Q2 ÷ ø è Dt ø 8.8 The Muskingum method of flood routing is a (a) form of reservoir routing method (b) hydraulic routing method (c) complete numerical solution of St Venant equations (d) hydrologic channel-routing method. 8.9 The Muskingum method of flood routing assumes the storage S is related to inflow rate I and outflow rate Q of a reach as S = (a) K[xI – (1 – x)Q] (b) K[xQ+ (1 – x)I] (c) K[xI + (1 – x)Q] (d) Kx[I – (1 – x)Q] 8.10 The Muskingum method of flood routing gives Q2 = C0I2 + C1I1 + C2Q1. The coefficients in this equation will have values such that (a) C0 + C1 = C2 (b) C0 – C1 – C2 = 1 (c) C0 + C1 + C2 = 0 (d) C0 + C1 + C2 = 1.

Flood Routing

319

8.11 The Muskingum channel routing equation is written for the outflow from the reach Q in terms of the inflow I and coefficients C0, C1 and C2 as (a) Q2 = C0 I0 + C1Q1 + C2I2 (b) Q2 = C0I2 + C1I1 + C2Q2 (c) Q2 = C0I0 + C1I1 +C2I2 (d) Q2 = C0Q0 + C1Q1 + C2I2 8.12 In the Muskingum method of channel routing the routing equation is written as Q2 = C0I2 + C1I1 + C2Q1, If the coefficients K = 12 h and x = 0.15 and the time step for routing Dt = 4 h, the coefficient C0 is (a) 0.016 (b) 0.048 (c) 0.328 (d) 0.656 8.13 In the Muskingum method of channel routing the weighing factor x can have a value (a) between –0.5 to 0.5 (b) between 0.0 to 0.5 (c) between 0.0 to 1.0 (d) between –1.0 to +1.0 8.14 In the Muskingum method of channel routing if x = 0.5, it represents an outflow hydrograph (a) that has reduced peak (b) with an amplified peak (c) that is exactly the same as the inflow hydrograph (d) with a peak which is exactly half of the inflow peak 8.15 If the storage S, inflow rate I and outflow rate Q for a river reach is written as S = K [x In + (1 – x) Qn] (a) n = 0 represents storage routing through a reservoir (b) n = 1 represents the Muskingum method (c) n = 0 represents the Muskingum method (d) n = 0 represents a linear channel. 8.16 A linear reservoir is one in which the (a) volume varies linearly with elevation (b) storage varies linearly with the outflow rate (c) storage varies linearly with time (d) storage varies linearly with the inflow rate. 8.17 An isochrone is a line on the basin map (a) joining raingauge stations with equal rainfall duration (b) joining points having equal standard time (c) connecting points having equal time of travel of the surface runoff to the catchment outlet (d) that connects points of equal rainfall depth in a given time interval. 8.18 In the Nash model for IUH given by u(t) =

1 (t/K)n–1 (e)–t/K K G(n)

the usual units of u(t), n and K are, respectively; (a) cm/h, h, h (b) h–1, h, h (c) h–1, dimensionless number, h (d) cm/h, dimensionless number, h 8.19 The peak ordinate of the IUH of a catchment was obtained from Nash model as 0.03 cm/ h. If the area of the catchment is 550 km2 the value of the peak ordinate in m3/s is (a) 16.5 (b) 45.83 (c) 30.78 (d) 183.3 8.20 If the Gamma function G (1.5) = 0.886, the value of G (0.5) is (a) 0.5907 (b) 1.329 (c) –0.886 (d) 1.772 8.21 In the Nash model for IUH, if MI1 = the first moment of ERH about the time origin divided by the total effective rainfall and MQ1 = the first moment of DRH about the time origin divided by the total direct runoff, then (a) MQ1 – MI 1 = nK (b) MI 1 – MQ1 = nK 2 (c) MQ1 – MI 1 = n (n + 1) K (d) MI 1 – MQ1 = 2 nK

Chapter

9

GROUNDWATER

9.1 INTRODUCTION In the previous chapters various aspects of surface water hydrology that deal with surface runoff have been discussed. Study of subsurface flow is equally important since about 30% of the world’s fresh water resources exist in the form of groundwater. Further, the subsurface water forms a critical input for the sustenance of life and vegetation in arid zones. Due to its importance as a significant source of water supply, various aspects of groundwater dealing with the exploration, development and utilization have been extensively studied by workers from different disciplines, such as geology, geophysics, geochemistry, agricultural engineering, fluid mechanics and civil engineering and excellent treatises are available, (Ref. 1, 2 and 4 through 10). This chapter confines itself to only an elementary treatment of the subject of groundwater as a part of engineering hydrology.

9.2 FORMS OF SUBSURFACE WATER Water in the soil mantle is called subsurface water and is considered in two zones (Fig. 9.1): 1. Saturated zone, and 2. Aeration zone.

Saturated Zone This zone, also known as groundwater zone, is the space in which all the pores of the soil are filled with water. The water taFig. 9.1 Classification of Subsurface Water ble forms its upper limit and marks a free surface, i.e. a surface having atmospheric pressure.

Zone of Aeration In this zone the soil pores are only partially saturated with water. The space between the land surface and the water table marks the extent of this zone. The zone of aeration has three subzones.

Groundwater

321

Soil Water Zone This lies close to the ground surface in the major root band of the vegetation from which the water is lost to the atmosphere by evapotranspiration. Capillary Fringe In this the water is held by capillary action. This zone extends from the water table upwards to the limit of the capillary rise. Intermediate Zone This lies between the soil water zone and the capillary fringe. The thickness of the zone of aeration and its constituent subzones depend upon the soil texture and moisture content and vary from region to region. The soil moisture in the zone of aeration is of importance in agricultural practice and irrigation engineering. The present chapter is concerned only with the saturated zone.

Saturated Formation All earth materials, from soils to rocks have pore spaces. Although these pores are completely saturated with water below the water table, from the groundwater utilization aspect only such material through which water moves easily and hence can be extracted with ease are significant. On this basis the saturated formations are classified into four categories: 1. Aquifer, 2. aquitard, 3. aquiclude, and 4. aquifuge. Aquifer An aquifer is a saturated formation of earth material which not only stores water but yields it in sufficient quantity. Thus an aquifer transmits water relatively easily due to its high permeability. Unconsolidated deposits of sand and gravel form good aquifers. Aquitard It is a formation through which only seepage is possible and thus the yield is insignificant compared to an aquifer. It is partly permeable. A sandy clay unit is an example of aquitard. Through an aquitard appreciable quantities of water may leak to an aquifer below it. Aquiclude It is a geological formation which is essentially impermeable to the flow of water. It may be considered as closed to water movement even though it may contain large amounts of water due to its high porosity. Clay is an example of an aquiclude. Aquifuge It is a geological formation which is neither porous nor permeable. There are no interconnected openings and hence it cannot transmit water. Massive compact rock without any fractures is an aquifuge. The definitions of aquifer, aquitard and aquiclude as above are relative. A formation which may be considered as an aquifer at a place where water is at a premium (e.g. arid zones) may be classified as an aquitard or even aquiclude in an area where plenty of water is available. The availability of groundwater from an aquifer at a place depends upon the rates of withdrawal and replenishment (recharge). Aquifers play the roles of both a transmission conduit and a storage. Aquifers are classified as unconfined aquifers and confined aquifers on the basis of their occurrence and field situation. An unconfined aquifer (also known as water table aquifer) is one in which a free water surface, i.e. a water table exists (Fig. 9.2). Only the saturated zone of this aquifer is of importance in groundwater studies. Recharge of this aquifer takes place through infiltration of

322 Engineering Hydrology precipitation from the ground surface. A well driven into an unconfined aquifer will indicate a static water level corresponding to the water table level at that location.

Fig. 9.2 Confined and Unconfined Acquifers A confined aquifer, also known as artesian aquifer, is an aquifer which is confined between two impervious beds such as aquicludes or aquifuges (Fig. 9.2). Recharge of this aquifer takes place only in the area where it is exposed at the ground surface. The water in the confined aquifer will be under pressure and hence the piezometric level will be much higher than the top level of the aquifer. At some locations: the piezometric level can attain a level higher than the land surface and a well driven into the aquifer at such a location will flow freely without the aid of any pump. In fact, the term artesian is derived from the fact that a large number of such freeflow wells were found in Artois, a former province in north France. Instances of free-flowing wells having as much as a 50-m head at the ground surface are reported. A confined aquifer is called a leaky aquifer if either or both of its confining beds are aquitards.

Water Table A water table is the free water surface in an unconfined aquifer. The static level of a well penetrating an unconfmed aquifer indicates the level of the water table at that point. The water table is constantly in motion adjusting its surface to achieve a balance between the recharge and outflow from the subsurface storage. Fluctuations in the water level in a dug well during various seasons of the year, lowering of the groundwater table in a region due to heavy pumping of the wells and the rise in the water table of an irrigated area with poor drainage, are some common examples of the fluctuation of the water table. In a general sense, the water table follows the topographic features of the surface. If the water table intersects the land surface the groundwater comes out to the surface in the form of springs or seepage. Sometimes a lens or localised patch of impervious stratum can occur inside an unconfined aquifer in such a way that it retains a water table above the general water table (Fig. 9.3). Such a water table retained around the impervious material is known as perched water table. Usually the perched water table is of limited extent and the

Groundwater

323

yield from such a situation is very small. In groundwater exploration a perched water table is quite often confused with a general water table. The position of the water table relative to the water level in a Fig. 9.3 Perched Water Table stream determines whether the stream contributes water to the groundwater storage or the other way about. If the bed of the stream is below the groundwater table, during periods of low flows in the stream, the water surface may go down below the general water table elevation and the groundwater contributes to the flow in the stream. Such streams which receive groundwater flow are called effluent streams (Fig. 9.4 (a)). Perennial rivers and streams are of this kind. If, however, the water table is below the bed of the stream, the stream-water percolates to the groundwater storage and a hump is formed in the groundwater table (Fig. 9.4 (b)). Such streams which contribute to the groundwater are known as influent streams. Intermittent rivers and streams which go dry during long periods of dry spell (i.e. no rain periods) are of this kind.

Fig. 9.4 Effluent and Influent Streams

9.3 AQUIFER PROPERTIES The important properties of an aquifer are its capacity to release the water held in its pores and its ability to transmit the flow easily. These properties essentially depend upon the composition of the aquifer.

Porosity The amount of pore space per unit volume of the aquifer material is called porosity. It is expressed as

324 Engineering Hydrology n=

Vv

(9.1) V0 where n = porosity, Vv = volume of voids and V0 = volume of the porous medium. In an unconsolidated material the size distribution, packing and shape of particles determine the porosity. In hard rocks the porosity is dependent on the extent, spacing and the pattern of fracturing or on the nature of solution channels. In qualitative terms porosity greater than 20% is considered as large, between 5 and 20% as medium and less than 5% as small. Specific Yield While porosity gives a measure of the water-storage capability of a formation, not all the water held in the pores is available for extraction by pumping or draining by gravity. The pores hold back some water by molecular attraction and surface tension. The actual volume of water that can be extracted by the force of gravity from a unit volume of aquifer material is known as the specific yield, Sy. The fraction of water held back in the aquifer is known as specific retention, Sr. Thus porosity (9.2) n = Sy + Sr The representative values of porosity and specific yield of some common earth materials are given in Table 9.1. Table 9.1 Porosity and Specific Yield of Selected Formations Formation

Porosity, %

Specific yield, %

Clay Sand Gravel Sand stone Shale Lime stone

45–55 35–40 30–40 10–20 1–10 1–10

1–10 10–30 15–30 5–15 0.5–5 0.5–5

It is seen from Table 9.1 that although both clay and sand have high porosity the specific yield of clay is very small compared to that of sand.

Darcy’s Law In 1856 Henry Darcy, a French hydraulic engineer, on the basis of his experimental findings proposed a law relating the velocity of flow in a porous medium. This law, known as Darcy’s law, can be expressed as V = Ki (9.3) where V = Apparent velocity of seepage = Q/A in which Q = discharge and A = crosssectional area of the porous medium. V is sometimes also known as discharge veloc-

dh = hydraulic gradient, in which h = piezometric head and s = distance ds measured in the general flow direction; the negative sign emphasizes that the piezometric head drops in the direction of flow. K = a coefficient, called coefficient of permeability, having the units of velocity.

ity. i = –

Groundwater

325

The discharge Q can be expressed as Q=KiA (9.3a) æ DH ö = K Aç è D s ÷ø where (– DH) is the drop in the hydraulic grade line in a length D s of the porous medium. Darcy’s law is a particular case of the general viscous fluid flow. It has been shown valid for laminar flows only. For practical purposes, the limit of the validity of Darcy’s law can be taken as Reynolds number of value unity, i.e. V da =1 (9.4) Re = v where Re = Reynolds number da = representative particle size, usually da = d10 where d10 represents a size such that 10% of the aquifer material is of smaller size. v = kinematic viscosity of water Except for flow in fissures and caverns, to a large extent groundwater flow in nature obeys Darcy’s law. Further, there is no known lower limit for the applicability of Darcy’s law. It may be noted that the apparent velocity V used in Darcy’s law is not the actual velocity of flow through the pores. Owing to irregular pore geometry the actual velocity of flow varies from point to point and the bulk pore velocity (va) which represents the actual speed of travel of water in the porous media is expressed as V (9.5) va = n where n = porosity. The bulk pore velocity va is the velocity that is obtained by tracking a tracer added to the groundwater.

Coefficient of Permeability The coefficient of permeability, also designated as hydraulic conductivity reflects the combined effects of the porous medium and fluid properties. From an analogy of laminar flow through a conduit (Hagen-Poiseuille flow) the coefficient of permeability K can be expressed as g K = Cd m2 (9.6) m where dm = mean particle size of the porous medium, g = rg = unit weight of fluid, r = density of the fluid, g = acceleration due to gravity, m = dynamic viscosity of the fluid and C = a shape factor which depends on the porosity, packing, shape of grains and grain-size distribution of the porous medium. Thus for a given porous material 1 Kµ v where v = kinematic viscosity = m/r = f(temperature). The laboratory or standard value of the coefficient of permeability (Ks) is taken as that for pure water at a standard temperature of 20° C. The value of Kt , the coefficient of permeability at any temperature t can be converted to Ks by the relation Ks = Kt(vt/vs) (9.7) where vs and vt represent the kinematic viscosity values at 20° C and t°C respectively.

326 Engineering Hydrology The coefficient of permeability is often considered in two components, one reflecting the properties of the medium only and the other incorporating the fluid properties. Thus, referring to Eq. (9.6), a term K0 is defined as g g K = K0 = K0 (9.8) v m where K0 = C d m2 . The parameter K0 is called specific or intrinsic permeability which is a function of the medium only. Note that K0 has dimensions of [L2]. It is expressed in units of cm2 or m2 or in darcys where 1 darcy = 9.87 ´ 10–13 m2. Where more than one fluid is involved in porous media flow or when there is considerable temperature variation, the coefficient K0 is useful. However, in groundwater flow problems, the temperature variations are rather small and as such the coefficient of permeability K is more convenient to use. The common units of K are m/day or cm/s. The conversion factor for these two are 1 m/day = 0.0011574 cm/s or 1 cm/s = 864.0 m/day Some typical values of coefficient of permeability of some porous media are given in Table 9.2. Table 9.2 Representative Values of the Permeability Coefficient No.

Material

A. Granular material 1. Clean gravel 2. Clean coarse sand 3. Mixed sand 4. Fine sand 5. Silty sand 6. Silt 7. Clay B. Consolidated material 1. Sandstone 2. Carbonate rock with secondary porosity 3. Shale 4. Fractured and weathered rock (aquifers)

K (cm/s)

K0 (darcys)

1–100 0.010–1.00 0.005–0.01 0.001–0.05 1 ´ 10–4 – 2 ´ 10–3 1 ´ 10–5 – 5 ´ 10–4 < 10–6

103–105 10–103 5–10 1–50 0.1–2 0.01–0.5 < 10–3

10–6 – 10–3 10–5 – 10–3

10–3 – 1.0 10–2 – 1.0

10–10 10 – 10–3

10–7 10 – 1.0

–6

–3

At 20° C, for water, v = 0.01 cm2/s and substituting in Eq. (9.8) K0 [darcys] = 103 K [cm/s] at 20°C

Consider an aquifer of unit width and thickness B, (i.e. depth of a fully saturated zone). The discharge through this aquifer under a unit hydraulic gradient is T = KB (9.9) This discharge is termed transmissibility, T and has the dimensions of [L2/T]. Its units are m2/s or litres per day/metre width (l pd/m). Typical values of T lie in the range 1 ´ 106 l pd/m to 1 ´ 104 l pd/m. A well with a value of T = 1 ´ 105 l pd/m is considered satisfactory for irrigation purposes.

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327

The coefficient of permeability is determined in the laboratory by a permeameter. For coarse-grained soils a constant-head permeameter is used. In this the discharge of water percolating under a constant head difference (DH) through a sample of porous material of cross-sectional area A and length L is determined. The coefficient of permeability at the temperature of the experiment is found as Q 1 K= A ( D H /L ) For fine grained soils, a falling-head permeameter is used. Details of permeameters and their use is available in any good textbook in Soil Mechanics, e.g. Ref. 8. It should be noted that laboratory samples are disturbed samples and a permeameter cannot simulate the field conditions exactly. Hence considerable care in the preparation of the samples and in conducting the tests are needed to obtain meaningful results. Under field conditions, permeability of an aquifer is determined by conducting pumping tests in a well. One of the many tests available for this purpose consists of pumping out water from a well at a uniform rate till steady state is reached. Knowing the steady-state drawdown and the discharge-rate, transmissibility can be calculated. Information about the thickness of the saturation zone leads one to calculate the permeability. Injection of a tracer, such as a dye and finding its velocity of travel is another way of determining the permeability under field conditions.

Stratification Sometimes the aquifers may be stratified, with different permeabilities in each strata. Two kinds of flow situations are possible in such a case. (i) When the flow is parallel to the stratification as in Fig. 9.5(a) equivalent permen

ability Ke of the entire aquifer of thickness B = å Bi is 1

n

å Ki Bi Ke =

1

(9.10)

n

å Bi 1

The transmissivity of the formation is n

T = Ke SBi = å KiBi 1

(ii) When the flow is normal to the stratification as in Fig. 9.5(b) the equivalent permeability Ke of the aquifer of length n

L = å Li is 1

n

å Li Ke =

1

n

(9.11)

å ( Li / Ki ) 1

(Note that in this case L is the length of seepage and the thickness B of the aquifer does not come into picture in calculating the equivalent permeability) The transmissivity of the aquifer is T = Ke × B

328 Engineering Hydrology

Fig. 9.5(a)

Flow Parallel to Stratification

Fig. 9.5(b) Flow Normal to Stratification

EXAMPLE 9.1 At a certain point in an unconfined aquifer of 3 km2 area, the water

table was at an elevation of 102.00 m. Due to natural recharge in a wet season, its level rose to 103.20 m. A volume of 1.5 Mm3 of water was then pumped out of the aquifer causing the water table to reach a level of 101.20 m. Assuming the water table in the entire aquifer to respond in a similar way, estimate (a) the specific yield of the aquifer and (b) the volume of recharge during the wet season.

SOLUTION: (a)

Volume pumped out 1.5 ´ 106 Sy (b) Recharge volume

= area ´ drop in water table ´ specified yield Sy = 3 ´ 106 ´ (103.20 – 101.20) ´ Sy = 0.25 = 0.25 ´ (103.20 – 102.00) ´ 3 ´ 106 = 0.9 Mm3

EXAMPLE 9.2 A field test for permeability consists in observing the time required for a tracer to travel between two observation wells. A tracer was found to take 10 h to travel between two wells 50 m apart when the difference in the water-surface elevation in them was 0.5 m. The mean particle size of the aquifer was 2 mm and the porosity of the medium 0.3. If v = 0.01 cm2/s estimate (a) the coefficient of permeability and intrinsic permeability of the aquifer and (b) the Reynolds number of the flow. SOLUTION:

(a) The tracer records the actual velocity of water Va =

50 ´ 100 10 ´ 60 ´ 60

= 0.139 cm/s

Discharge velocity V = n Va = 0.3 ´ 0.139 = 0.0417cm/s Hydraulic gradient i =

0.50 = 1 ´ 10–2 50

Coefficient of permeability K = Intrinsic permeability,

K0 =

4.17 ´ 10 –2 1 ´ 10 –2

= 4.17 cm/s

4.17 ´ 0.01 Kv = = 4.25 ´ 10–5 cm2 g 981

Since 9.87 ´ 10–9 cm2 = 1 darcy K0 = 4307 darcys

Groundwater (b) Reynolds number

Re =

329

Vd a v

Taking da = mean particle size = 2 mm Re =

0.0417 ´ 2 10

´

1 = 0.834. 0.01

EXAMPLE 9.3 Three wells A, B and C tap the same horizontal aquifer. The distances AB = 1200 m and BC = 1000 m. The well B is exactly south of well A and the well C lies to the west of well B. The following are the ground surface elevation and depth of water below the ground surface in the three wells. Well

Surface Elevation (metres above datum)

Depth of water table (m)

A B C

200.00 197.00 202.00

11.00 7.00 14.00

Determine the direction of groundwater flow in the aquifer in the area ABC of the wells.

SOLUTION: Let H = elevation of water table. HA = 200.00 – 11.00 = 189.00 HB = 197.00 – 7.00 = 190.00 HC = 202.00 – 14.00 = 188.00 Let BA = North direction, designated as Y direction. The West direction will be called X direction. The layout of the wells is shown in Fig. 9.6 Along BA: –DHy = HB – HA = 190.00 – 189.00 = 1.00 m iy = -

DHy

=

LAB

1.00 = 1/1200. 1200

Fig. 9.6 Layout of Wells

Vy = K × iy = K/1200 m/s where K = coefficient of permeability. Along BC, (X direction): – DHx = HB – HC = 190.00 – 188.00 = 2.00 m ix = -

D Hx LBC

=

2.00 = 1/500. 1000

Vx = K × ix = K/500 m/s V = (V 2x + V 2y)1/2 = tan q =

Vy Vx

=

1/ 2

K é1 1 ù + 100 êë 25 144 úû

500 K 1 ´ = K 1200 2.4

q = 22.62° = 22° 37¢ 11.5²

= 2.167 ´ 10–3 K m/s

330 Engineering Hydrology where q = inclination of V to X-axis (west direction). The groundwater flow will be in a direction which makes 22.62° with line BC and 67.38° with BA. Thus, the direction of groundwater flow is N 67° 27¢ 48.5² W.

9.4 GEOLOGIC FORMATIONS AS AQUIFERS The identification of a geologic formation as a potential aquifer for groundwater development is a specialized job requiring the services of a trained hydrogeologist. In this section only a few general observations are made and for details the reader is referred to a standard treatise on hydrogeology such as Ref. 4. The geologic formations of importance for possible use as an aquifer can be broadly classified as (i) unconsolidated deposits, and (ii) consolidated rocks. Unconsolidated deposits of sand and gravel form the most important aquifers. They occur as fluvial alluvial deposits, abandoned channel sediments, coastal alluvium and as lake and glacial deposits. The yield is generally good and may be of the order of 50–100 m3/h. In India, the Gangetic alluvium and the coastal alluvium in the states of Tamil Nadu and Andhra Pradesh are examples of good aquifers of this kind. Among consolidated rocks, those with primary porosity such as sandstones are generally good aquifers. Weathering of rocks and occurrence of secondary openings such as joints and fractures enhance the yield. Normally, the yield from these aquifers is less than that of alluvial deposits and typically may have a value of 20–50 m3/h. Sandstones of Kathiawar and Kutch areas of Gujarat and of Lathi region of Rajasthan are some examples. Limestones contain numerous secondary openings in the form of cavities formed by the solution action of flowing subsurface water. Often these form highly productive aquifers. In Jodhpur district of Rajasthan, cavernous limestones of the Vindhyan system are providing very valuable groundwater for use in this arid zone. The volcanic rock basalt has permeable zones in the form of vesicles, joints and fractures. Basaltic aquifers are reported to occur in confined as well as under unconfined conditions. In the Satpura range some aquifers of this kind give yields of about 20 m3/h. Igneous and metamorphic rocks with considerable weathered and fractured horizons offer good potentialities as aquifers. Since weathered and fractured horizons are restricted in their thickness these aquifers have limited thickness. Also, the average permeability of these rocks decreases with depth. The yield is fairly low, being of the order of 5–10 m3/h. Aquifers of this kind are found in the hard rock areas of Karnataka, Tamil Nadu, Andhra Pradesh and Bihar.

9.5 COMPRESSIBILITY OF AQUIFERS In confined aquifers the total pressure at any point due to overburden is borne by the combined action of the pore pressure and intergranular pressure. The compressibility of the aquifer and also that of the pore water causes a readjustment of these pressures whenever there is a change in storage and thus have an important bearing on the storage characteristics of the aquifer. In this section a relation is developed between a defined storage coefficient and the various compressibility parameters. Consider an elemental volume DV = (DxDy) DZ = DA DZ of a compressible aquifer as shown in Fig. 9.7. A cartesian coordinate system with the Z-axis pointing vertically upwards is adopted. Further the following three compressible aquifer assumptions are made:

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331

The elemental volume is constrained in lateral directions and undergoes change of length in the z-direction only, i.e. DA is constant. l The pore water is compressible l The solid grains of the aquifer are incompressible but the pore structure is compressible. By defining the reciprocal of the bulk modulus of elasticity of water as compressibility of water b, it is written as Fig. 9.7 Volume element of a compressible aquifer ( d DVw ) / dp (9.12) b= D Vw where DVw = volume of water in the chosen element of aquifer, and p = pressure. By conservation of mass r × D Vw = constant, where r = density of water. Thus r d(D Vw) + DVw dr = 0 Substituting this relationship in Eq. (9.12), b = dr/(r dp) (9.13) l

or

dr = rbdp (9.13a) Similarly by considering the reciprocal of the bulk modulus of elasticity of the pore-space skeleton as the compressibility of the pores, a, it is expressed as d ( D V )/ DV a= (9.14) ds z in which sz = intergranular pressure. Since DV = DA × DZ with DA = constant, d ( D Z )/ D Z (9.15) a= ds z The total overburden pressure w = p + sz = constant. Thus dp = –d sz, which when substituted in Eq. (9.15) gives d (DZ) = a (DZ) dp (9.16) As the volume of solids D Vs in the elemental volume is constant, D Vs = (1 – n) DA × DZ = constant d(D Vs) = (1 – n) d (DZ) – DZ × dn = 0 where n = porosity of the aquifer. Using this relationship in Eq. (9.16), dn = a (1 – n) dp (9.17) Now, the mass of water in the element of volume DV, is DM = rn DA DZ or i.e.

d (D Z ) ù é d(DM) = D V ên d r + r dn + rn D Z úû ë d (D M ) d (D Z ) dr + dn + n = n r DV r DZ

332 Engineering Hydrology Substituting from Eqs. (9.13), (9.17) and (9.15) for the terms in the right-hand side respectively d (DM ) = nb dp + a (1 – n) dp + n a dp = (nb + a) dp r DV = g (nb + a) dh = Ssdh (9.18) r and g = rg = weight of unit where Ss = g (n b + a) and h = piezometric head = z + g volume of water. The term Ss is called specific storage. It has the dimensions of [L–1] and represents the volume of water released from storage from a unit volume of aquifer due to a unit decrease in the piezometric head. The numerical value of Ss is very small being of the order of 1 ´ 10–4 m–1. By integration of Eq. (9.18) for a confined aquifer of thickness B, a dimensionless storage coefficient S can be expressed as S = g (nb + a) B (9.19) The storage coefficient S (also known as Storativity) represents the volume of water released by a column of a confined aquifer of unit cross-sectional area under a unit decrease in the piezometric head. The storage coefficient S and the transmissibility coefficient T are known as the formation constants of an aquifer and play very important role in the unsteady flow through the porous media. Typical values of S in confined aquifers lie in the range 5 ´ 10–5 to 5 ´ 10–3. Values of a for some formation material and b for various temperatures are given in Tables 9.3 and 9.4 respectively. Table 9.3 Range of a for Some Formation Materials Material Loose clay Stiff clay Loose sand Dense sand Dense sandy gravel Fissured and jointed rock

Bulk modulus of elasticity, Es (N/cm2)

Compressibility a = 1/Es (cm2/N)

102 – 5 ´ 102 103 – 104 103 – 2 ´ 103 5 ´ 103 – 8 ´ 103 104 – 2 ´ 104 1.5 ´ 104 – 3 ´ 105

10–2 – 2 ´ 10–3 10–3 – 10–4 10–3 – 5 ´ 10–4 2 ´ 10–4 – 1.25 ´ 10–4 10–4 – 5 ´ 10–5 6.7 ´ 105 – 3.3 ´ 10–6

Table 9.4 Values of b for Water at Various Temperatures Temperature (°C)

Bulk modulus of elasticity, Ew (N/cm2)

Compressibility b = 1/Ew (cm2/N)

0 10 15 20 25 30 35

2.04 ´ 105 2.11 ´ 105 2.14 ´ 105 2.20 ´ 105 2.22 ´ 105 2.23 ´ 105 2.24 ´ 105

4.90 ´ 10–6 4.74 ´ 10–6 4.67 ´ 10–6 4.55 ´ 10–6 4.50 ´ 10–6 4.48 ´ 10–6 4.46 ´ 10–6

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333

For an unconfined aquifer, the coefficient of storage is given by S = Sy + g (a + nb) Bs (9.20) where Bs = saturated thickness of the aquifer. However, the second term on the righthand side is so small relative to Sy that for practical purposes S is considered equal to Sy, i.e. the coefficient of storage is assumed to have the same value as the specific yield for unconfined aquifers. The elasticity of the aquifer is reflected dramatically in the response of the water levels in the wells drilled in confined aquifers to changes in the atmospheric pressure. Increase in the atmospheric pressure causes an increase in the loading of the aquifer. The change in the pressure is balanced by a partial compression of the water and partial compression of the pore skeleton. An increase in the atmospheric pressure causes a decrease in the water level in the well. Converse is the case with the decrease in pressure. The ratio of the water level change to pressure head change is called barometric efficiency (BE) and is given in terms of the compressibility parameters as æ nb ö BE = - ç (9.21) è a + nb ÷ø The negative sign indicates the opposite nature of the changes in pressure head and water level. Using in Eq. (9.21) (Eq. 9.19), BE = –nb/g S B and this affords a means of finding S. The barometric efficiency can be expected to be in the range 10–75%. It is apparent that unconfined aquifers have practically no barometric efficiency. A few other examples of compressibility effects causing water level changes in artesian wells include (i) tidal action in coastal aquifers, (ii) earthquake or underground explosions, and (iii) passing of heavy railway trains.

9.6 EQUATION OF MOTION Confined Groundwater Flow If the velocities of flow in the cartesian coordinate directions x, y, z of the aquifer element, DV, are u, v and w respectively, the equation of continuity for the fluid flow is

¶(D M )

é ¶ ( r u ) ¶ ( r v ) ¶ ( r w) ù = -ê (9.22) + + ¶t ¶y ¶z úû ë ¶x From Eq. (9.18) considering the differentials with respect to time and taking the limit as DV approaches zero ¶(D M ) dh = Ssr (9.18a) dt ¶t Further the aquifer is assumed to be isotropic with permeability coefficient K, so that the Darcy’s equation for x, y and z directions can be written as ¶h ¶h ¶h u = -K , v = -K and w = - K (9.23) ¶x ¶z ¶y p + z, the various terms of the rightUsing Eqs. (9.23) and (9.13) and noting that h = g hand side of Eq. (9.22) are written as

¶ ( r u) ¶x

= r

2 ¶r ¶u ¶2 h ¶h +u = -K r - K r2 b g æ ö è ¶x ø ¶x ¶x ¶x 2

334 Engineering Hydrology

¶ (r v) ¶r æ ¶h ö ¶v ¶2 h = r +v = -K r - K r2 b g ç ÷ 2 ¶y ¶y ¶y è ¶y ø ¶y

2

é ¶h 2 ¶h ù ¶r ¶w ¶2 h +w = -K - K r 2 b g êæ ö - ú ¶z ¶z ¶z úû ¶z ¶z 2 êëè ¶z ø Assembling these, Eq. (9.22) can be written as

¶ ( r w)

= r

2ù é ¶h 2 æ ¶h ö 2 êæ ö + ç ÷ + æ ¶h ö ú - ¶h = r S s ¶h è ¶z ø ú ¶z ¶t è ¶y ø êëè ¶x ø û (9.24) The second term on the left-hand side is neglected as very small, especially for ¶h/¶x = 1, and Eq. (9.24) is rearranged to yield ¶2 h ¶2 h ¶2 h S s ¶h (9.25) + + = K ¶t ¶x 2 ¶y 2 ¶z 2 æ ¶2 h ¶2 h ¶2 h ö Defining SsB = S, K B = T, and Ñ2 h = ç + + ÷ , Eq. (9.25) reads as è ¶x 2 ¶y 2 ¶z 2 ø S ¶h (9.26) Ñ2h = T ¶t This is the basic differential equation governing unsteady groundwater flow in a homogeneous isotropic confined aquifer. This form of the equation is known as diffusion equation. If the flow is steady, the ¶h/¶t term does not exist, leading to (9.27) Ñ2h = 0 This equation is known as Laplace equation and is the fundamental equation of all potential flow problems. Being linear, the method of superposition is applicable in its solutions. Equation (9.26) or (9.27) can be solved for suitable boundary conditions by analytical, numerical or analog methods to yield solutions to a variety of groundwater flow problems. The details of solution of the basic differential equation of groundwater are available in standard literature (Refs. 1, 3, 5, 6 and 7). As an application of the Laplace equation (Eq. 9.27) a simple situation of steady state one-dimensional confined porous media flow is given below.

é ¶2 h ¶2 h ¶2 h ù 2 + + Kr ê ú + Kr bg 2 2 2 x y z ¶ ¶ ¶ ëê ûú

Confined Groundwater Flow between Two Water Bodies Figure 9.8 shows a very wide confined aquifer of depth B connecting to water bodies. A section of the aquifer of unit width is considered. The piezometric head at the upstream end is h0 and at a distance x from the upstream end the head is h. As the flow is in x direction only, Eq. (9.27) becomes ¶2 h =0 ¶x 2 On integrating twice h = C1 x + C2 On substitution of the boundary condition h = h0 at x = 0 h = C1x + h0

(9.28)

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335

Fig. 9.8 Confined Groundwater Flow between Two Water Bodies

æ h0 - h1 ö x = L, h = h1 and hence C1 = - ç è L ÷ø æ h0 - h1 ö x Thus h = h0 – ç (9.29) è L ÷ø This is the equation of the hydraulic grade line, which is shown to vary linearly from h0 to h1. By Darcy law, the discharge per unit width of the aquifer is dh = – KB (– (h0 – h1)/L) q = –KB dx ( h0 - h1 ) KB (9.30) q= L Also at

Unconfined Flow by Dupit’s Assumption While Eq. (9.26) is specifically for confined aquifers, Eq. (9.27) which is the Laplace equation in h is applicable to steady flow of both confined and unconfined aquifers. However, in unconfined aquifers the free surface of the water table, known as phreatic surface, has the boundary condition of constant pressure equal to atmospheric pressure. Also, in a section the line representing the water table, is also a streamline. These boundary conditions cause considerable difficulties in analytical solutions of steady unconfined flow problems by using the Laplace equation in h. A simplified approach based on the assumptions suggested by Dupit (1863) which gives reasonably good results is described below. The basic assumptions of Dupit are: l The curvature of the free surface is very small so that the streamlines can be assumed to be horizontal at all sections. l The hydraulic grade line is equal to the free surface slope and does not vary with depth. Consider an elementary prism of fluid bounded by the water table shown in Fig. 9.9(a).

336 Engineering Hydrology Let Vx = gross velocity of groundwater entering the element in x direction Vy = gross velocity of groundwater entering the element in y direction Assume a horizontal impervious base and no vertical inflow from top due to recharge. By Dupit’s assumptions, ¶Vx /¶z = 0 and ¶Vy /¶z = 0. Considering the X diFig. 9.9(a) rection: The mass flux entering the element Mx1 = r Vx h D y

Definition Sketch—Unconfined Groundwater Flow without Recharge

¶ (rVx h Dy) Dx ¶x The net mass efflux from the element in x direction, by considering the flow entering the element as positive and outflow as negative, is ¶ Mxl – Mx2 = D Mx = - (rVxh Dy) Dx ¶x Similarly the net mass efflux in y direction ¶ Myl – My2 = D My = - (rVyh Dx) Dy ¶y Further, there is neither inflow or outflow in the Z direction. Thus for steady, incompressible flow, by continuity D Mx + D My = 0 (9.31) Substituting for D Mx and D My and simplifying The mass flux leaving the element Mx2 = rVxh Dy +

¶ ¶ (Vx h) + (V h) = 0 ¶x ¶y y ¶h ¶h By Darcy law Vx = - K and Vy = - K ¶x ¶y Hence Eq. (9.32) becomes

(9.32)

¶ æ ¶h ¶ æ ¶h ö -K h ö + ç-K h ÷ = 0 è ø ¶x ¶x ¶y è ¶y ø or

¶2 h 2 ¶2 h 2 + =0 ¶x 2 ¶y 2

i.e. (9.33) Ñ2h2 = 0 Thus the steady unconfined groundwater flow with Dupit’s assumptions is governed by Laplace equation in h2.

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337

Unconfined Flow with Recharge If there is a recharge, i.e. infiltration of water from the top ground surface into the aquifer, at a rate of R (m3/s per m2 of horizontal area) as in Fig. 9.9(b), the continuity equation Eq. (9.31) is to be modified to take into account the recharge. Consider the element of an uncon-fined aquifer as in Fig. 9.9(b) situated on a horizontal impervious bed. Here, in addition to D Mx and D My there will be a net inflow into the element in the Z direction given by Fig. 9.9(b) Definition Sketch – Unconfined flow with Recharge D Mz = r R Dx Dy For steady, incompressible flow the continuity relationship for the element is D Mx + D My + D Mz = 0 i.e.

-

¶ ¶ (r Vx h Dx Dy) - (r Vy h Dx Dy) + r R Dx Dy = 0 ¶x ¶y

Substituting Vx = - K

¶h ¶h and Vy = - K and simplifying ¶x ¶y

2R ¶2 h 2 ¶2 h 2 + = 2 2 K ¶x ¶y

(9.34)

Equation (9.34) is the basic differential equation under Dupit’s assumption for unconfined groundwater flow with recharge. Note that Eq. (9.33) is a special case of Eq. (9.34) with R = 0. Use of Eq. (9.34) finds considerable practical application in finding the water table profiles in unconfined aquifers. A few examples are: (i) an unconfined aquifer separating two water bodies such as a canal and a river, (ii) various recharge situations, (iii) drainage problems, and (iv) infiltration galleries. To illustrate the use of Eq. (9.34) a situation of steady flow in an unconfined aquifer bounded by two water bodies and subjected to recharge from top is given below. One Dimensional Dupit’s Flow with Recharge (1) The general case Consider an unconfined aquifer on a horizontal impervious base situated between two water bodies with a difference in surface elevation, as shown in Fig. 9.10. Further, there is a recharge at a constant rate of R m3/s per unit horizontal area due to infiltration from the top of the aquifer. The aquifer is of infinite length and

338 Engineering Hydrology hence one dimensional method of analysis is adopted. A unit width of aquifer is considered for analysis. 2R ¶2 h 2 = (9.35) From Eq. (9.34) 2 K ¶x On integration with resprect to x twice, R h2 = - x2 + C1x + C2 (9.36) K where C1 and C2 are constants of integration

Fig. 9.10 One Dimensional Dupit Flow with Recharge The boundary conditions are: (i) at x = 0, h = h0 hence, C2 = h20 (ii) at x = L, h = h1 hence, h21 – h20 = -

or

C1 = -

R 2 L + C1L K

æ 2 RL2 ö 2 çè h0 - h1 - K ÷ø

Thus Eq. (9.36) becomes

L æ 2 RL2 ö 2 çè h0 - h1 - K ÷ø

Rx 2 x + h02 (9.37) K L The water table is thus an ellipse represented by Eq. (9.37). The value of h will in general rise above h0, reaches a maximum at x = a and falls back to h1 at x = L as h2 = -

Groundwater

shown in Fig. 9.10. The value of a is obtained by equating

339

dh = 0, and is given by dx

2 2 L K æ h0 - h1 ö (9.38) a= ç ÷ 2 R è 2L ø The location x = a is called the water divide. Figure 9.10 shows the flow to the left of the divide will be to the upstream water body and the flow to the right of the divide will be to the downstream water body. The discharge per unit width of aquifer at any location x is

é ê Rx dh = - K êqx = –K h ê K dx ê ëê

æ 2 RL2 2 çè h0 - h1 - K 2L

öù ø÷ úú ú ú ûú

L K 2 ( h - h12 ) qx = R æ x - ö + (9.39) è 2 ø 2L 0 It is obvious the discharge qx varies with x. At the upstream water body, x = 0 and RL K 2 + Discharge q0 = qx = 0 = (9.40) ( h - h12 ) 2 2L 0 At the downstream water body, x = L and RL K 2 + q1 = qx = L = (9.40a) ( h - h12 ) = RL + q0 2 2L 0 (2) Flow without recharge When there is no recharge, R = 0 and the flow simplifies to that of steady one-dimensional flow in an unconfined aquifer as in Fig. 9.11.

Fig. 9.11 One Dimensional Unconfined Flow without Recharge By putting R = 0 in Eq. (9.37), the equation of the water table is given by

æ h12 - h02 ö (h2 – h20) = ç ÷x L ø è

(9.41)

340 Engineering Hydrology This represents a parabola (known as Dupit’s parabola) joining h0 and h1 on either side of the aquifer. Differentiating Eq. (9.41) with respect to x

( h12 - h02 ) dh = dx L The discharge q per unit width of the aquifer is 2h

q=–Kh

( h02 - h12 ) dh = K dx 2L

(9.42)

(3) Tile drain problem The provision of drains system is one of the most widely used method of draining waterlogged areas, the object being to reduce the level of the water table. Figure 9.12 shows a set of porous tile drains maintaining a constant recharge rate of R at the top ground surface.

Fig. 9.12 Tile Drains under a Constant Recharge Rate An approximate expression to the water table profile can be obtained by Eq. (9.37) by neglecting the depth of water in the drains, i.e. h0 = h1 = 0. The water table profile will then be R (L – x) x (9.43) h2 = K The maximum height of the water table occurs at a = L/2 and is of magnitude L R/K hm = (9.44) 2 Considering a set of drains, since the flow is steady, the discharge entering a drain per unit length of the drain is L q = 2 æ R ö = RL (9.45) è 2ø EXAMPLE 9.4 Two parallel rivers A and B are separated by a land mass as shown in Fig. 9.13. Estimate the seepage discharge from River A to River B per unit length of the rivers.

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341

Fig. 9.13 Schematic Layout of Example 9.4 SOLUTION: The aquifer system is considered as a composite of aquifers 1 and 2 with a horizontal impervious boundary at the interface. This leads to the assumptions: (a) aquifer 2 is a confined aquifer with K2 = 10 m/day (b) aquifer 1 is an unconfined aquifer with K1 = 25 m/day

Consider a unit width of the aquifers. For the confined aquifer 2: ( h0 - h1 ) From Eq. (9.30) q2 = KB L Here h0 = 35.0 m, h1 = 15 m, L = 3000 m, K2 = 10 m/day and B = 10 m (35 - 15) q2 = ´ 10 ´ 10 = 0.667 m3/day per metre width 3000 For the unconfined aquifer 1: From Eq. (9.42), q1 = Here

( h02 - h12 )

2L h0 = (35 – 10) = 25 m, L = 3000 m,

K

h1 = (15 – 10) = 5 m K1 = 25 m/day

(25) 2 - (5) 2

´ 25 = 2.5 m3/day per metre width 2 ´ 3000 Total discharge from river A to river B = q = q1 + q2 = 0.667 + 2.500 = 3.167 m3/day per unit length of the rivers q2 =

EXAMPLE 9.5 An unconfined aquifer (K = 5 m/day) situated on the top of a horizontal impervious layer connects two parallel water bodies M and N which are 1200 m apart. The water surface elevations of M and N, measured above the horizontal impervious bed, are 10.00 m and 8.00 m. If a uniform recharge at the rate of 0.002 m3/day per m2 of horizontal area occurs on the ground surface, estimate (i) (ii) (iii) (iv)

the water table profile the location and elevation of the water table divide the seepage discharges into the lakes and the recharge rate at which the water table divide coincides with the upstream edge of the aquifer and the total seepage flow per unit width of the aquifer at this recharge rate.

342 Engineering Hydrology SOLUTION: Consider unit width of the aquifer Referring to Fig. 9.14 h0 = 10.0 m, h1 = 8.0 m, R = 0.002 m3/day/m2, L = 1200 m and K = 5 m/day.

Fig. 9.14 Schematic Layout—Example 9.5 (i) The water table profile:

By Eq. (9.37), h2 = -

2

Rx K

æ 2 RL2 ö 2 çè h0 - h1 - K ø÷ L

x + h02

0.002 ´ (1200)2 ù 1 é æ 0.002 ö 2 2 2 x (10) (8) ê ú x + 102 = ç è 5 ÷ø 1200 êë 5 ûú h2 = –0.0004 x2 + 0.45x + 100 (ii) Location of water table divide: From Eq. (9.38)

a=

2 2 L K æ h0 - h1 ö - ç ÷ 2 R è 2L ø

a=

2 2 1200 æ 5.0 ö æ (10) - (8) ö = 562.5 m -ç ÷ ç è 0.002 ø è 2 ´ 1200 ø÷ 2

At x = a = 562.5 m, h = hm = height of water table divide h 2m = –0.0004 (562.5)2 + 0.45 (562.5) + 100 = 226.56 and hm = 226.56 = 15.05 m (iii) Discharge per unit width of the aquifer:

æ è

From Eq. (9.39) qx = R ç x -

Lö K 2 ( h - h12 ) ÷+ 2ø 2L 0

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343

L K 2 + ( h - h12 ) 2 2L 0 - (0.002 ´ 1200) 5 + [(10)2 - (8)2 ] = –1.20 + 0.075 = 2 2 ´ 1200 q0 = –1.125 m3/day per metre width The negative sign indicates that the discharge is in (–x) direction, i.e. into the water body M. At x = L, q1 = qL and from Eq. (9.40a) qL = RL + q0 Hence q1 = discharge into water body N = 0.002 ´ 1200 + (–1.125) = 1.275 m3/day/m width. (vi) when the distance of the water table divide a = 0: At x = 0,

q0 = - R

From Eq. (9.36), a =

2 2 L K æ h0 - h1 ö - ç ÷ =0 2 R è 2L ø

2 2 K æ h0 - h1 ö L = çè ÷ R 2L ø 2

R=

5.0 K 2 [(10)2 - (8)2 ] ( h0 - h12 ) = 2 2 (1200) L

= 1.25 ´ 10–4 m3/day/m2 Since a = 0, q0 = 0 and by Eq. (9.40a) q1 = qL = RL = 1.25 ´ 10–4 ´ 1200 = 0.15 m3/day/m width.

9.7

WELLS

Wells form the most important mode of groundwater extraction from an aquifer. While wells are used in a number of different applications, they find extensive use in water supply and irrigation engineering practice. Consider the water in an unconfined aquifer being pumped at a constant rate from a well. Prior to the pumping, the water level in the well indicates the static water table. A lowering of this water level takes place on pumping. If the aquifer is homogeneous and isotropic and the water table horizontal initially, due to the radial flow into the well through the aquifer the water table assumes a conical shape called cone of depression. The drop in the water table elevation at any point from its previous static level is called drawdown. The areal extent of the cone of depression is called area of influence and its radial extent radius of influence (Fig. 9.15). At constant rate of pumping, the drawdown curve develops gradually with time due to the withdrawal of water from storage. This phase is called an unsteady flow as the water table elevation at a given location near the well changes with time. On prolonged pumping, an equilibrium state is reached between the rate of pumping and the rate of inflow of groundwater from the outer edges of the zone of influence. The drawdown surface attains a constant position with respect to time when the well is known to operate under steadyflow conditions. As soon as the pumping is stopped, the depleted storage in the cone of depression is made good by groundwater inflow into the zone of influence. There is a gradual accumulation of storage till the original (static) level is reached. This stage

344 Engineering Hydrology is called recuperation or recovery and is an unsteady phenomenon. Recuperation time depends upon the aquifer characteristics.

Fig. 9.15 Well Operating in an Unconfined Aquifer, (definition sketch) Changes similar to the above take place to a pumping well in a confined aquifer also but with the difference that it is the piezometric surface instead of the water table that undergoes drawdown with the development of the cone of depression. In confined aquifers with considerable piezometric head, the recovery into the well takes place at a very rapid rate.

9.8 STEADY FLOW INTO A WELL Steady state groundwater problems are relatively simpler. Expressions for the steady state radial flow into a well under both confined and unconfined aquifer conditions are presented below.

Confined Flow Figure 9.16 shows a well completely penetrating a horizontal confined aquifer of thickness B. Consider the well to be discharging a steady flow, Q. The original piezometric head (static head) was H and the drawdown due to

Fig. 9.16 Well Operating in a Confined Aquifer

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345

pumping is indicated in Fig. 9.16. The piezometric head at the pumping well is hw and the drawdown sw. At a radial distance r from the well, if h is the piezometric head, the velocity of flow by Darcy’s law is dh Vr = K dr The cylindrical surface through which this velocity occurs is 2p r B. Hence by equating the discharge entering this surface to the well discharge, Q dr dh = dh Q = (2 p r B) æ K ö è dr ø 2 p KB r Integrating between limits r1 and r2 with the corresponding piezometric heads being h1 and h2 respectively, r2 Q = (h2 – h1) ln 2 p KB r1 2 p KB ( h2 - h1 ) or Q= (9.46) r2 ln r1 This is the equilibrium equation for the steady flow in a confined aquifer. This equation is popularly known as Thiem’s equation. If the drawdown s1 and s2 at the observation wells are known, then by noting that s1 = H – h1, s2 = H – h2 and KB = T Equation (9.46) will read as 2 p T ( s1 - s2 ) Q= (9.47) r2 ln r1 Further, at the edge of the zone of influence, s = 0, r2 = R and h2 = H; at the well wall r1 = rw, h1 = hw and s1 = sw. Equation (9.47) would then be 2 p T sw (9.48) Q= ln R/rw Equation (9.47) or (9.48) can be used to estimate T, and hence K, from pumping tests. For the use of the equilibrium equation, Eq. (9.46) or its alternative forms, it is necessary that the assumption of complete penetration of the well into the aquifer and steady state of flow are satisfied. EXAMPLE 9.6 A 30-cm diameter well completely penetrates a confined aquifer of permeability 45 m/day. The length of the strainer is 20 m. Under steady state of pumping the drawdown at the well was found to be 3.0 m and the radius of influence was 300 m. Calculate the discharge. SOLUTION: In this problem, referring to Fig. 9.16, rw = 0.15 m R = 300 m sw = 3.0 m K = 45/(60 ´ 60 ´ 24) = 5.208 ´ 10–4 m/s T = KB = 10.416 ´ 10–3 m2/s

B = 20 m

346 Engineering Hydrology By Eq. (9.48) Q=

2 p T sw ln R/rw

=

2 p ´ 10.416 ´ 10-3 ´ 3 300 ln 0.15

= 0.02583 m3/s = 25.83 lps = 1550 lpm

EXAMPLE 9.7 For the well in the previous example, calculate the discharge (a) if the well diameter is 45 cm and all other data remain the same as in Example 9.6(b) if the drawdown is increased to 4.5 m and all other data remain unchanged as in Example 9.6. SOLUTION: (a) Q =

2 p T sw ln R/rw

As T and sw are constants,

Q1 Q2

=

ln R/rw2 ln R/rw1

Putting R = 300 m Q1 = 1550 lpm, rw1 = 0.15 m and rw2 = 0.225 m. Q2 = 1550

ln 300/0.15

ln 300/0.225

= 1637 lpm

[Note that the discharge has increased by about 6% for 50% increase in the well diameter.] (b) Q =

2 p T sw ln R/rw

Q a sw for constant T, R and rw. Thus

Q1

Q2

=

sw1

sw2

Q2 = 1550 ´

4.5 =2325 lpm 3.0

[Note that the discharge increases linearly with the drawdown when other factors remain constant.]

Unconfined Flow Consider a steady flow from a well completely penetrating an unconfined aquifer. In this case because of the presence of a curved free surface, the streamlines are not strictly radial straight lines. While a streamline at the free surface will be curved, the one at the bottom of the aquifer will be a horizontal line, both converging to the well. To obtain a simple solution Dupit’s assumptions as indicated in Sec. 9.6 are made. In the present case these are: · For small inclinations of the free surface, the streamlines can be assumed to be horizontal and the equipotentials are thus vertical. · The hydraulic gradient is equal to the slope of the free surface and does not vary with depth. This assumption is satisfactory in most of the flow regions except in the immediate neighbourhood of the well. Consider the well of radius rw penetrating completely an extensive unconfined horizontal aquifer as shown in Fig. 9.17. The well is pumping a discharge Q. At any radial distance r, the velocity of radial flow into the well is

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347

Fig. 9.17 Radial Flow to a Well in an Unconfined Aquifer

dh dr where h is the height of the water table above the aquifer bed at that location. For steady flow, by continuity dh Q = (2 p r h)Vr = 2 p r K h dr Q dr or = h dh 2pK r Integrating between limits r1 and r2 where the water-table depths are h1 and h2 respectively and on rearranging Vr = K

Q=

p K ( h22 - h12 )

(9.49) r2 r1 This is the equilibrium equation for a well in an unconfined aquifer. As at the edge of the zone of influence of radius R, H = saturated thickness of the aquifer, Eq. (9.49) can be written as ln

Q=

p K ( H 2 - hw2 )

(9.50) ln R rw where hw = depth of water in the pumping well of radius rw. Equations (9.49) and (9.50) can be used to estimate satisfactorily the discharge and permeability of the aquifer by using field data. Calculations of the water-table profile by Eq. (9.49), however, will not be accurate near the well because of Dupit’s

348 Engineering Hydrology assumptions. The water-table surface calculated by Eq. (9.49) which involved Dupit’s assumption will be lower than the actual surface. The departure will be appreciable in the immediate neighbourhood of the well (Fig. 9.17). In general, values of R in the range 300 to 500 m can be assumed depending on the type of aquifer and operating conditions of a well. As the logarithm of R is used in the calculation of discharge, a small error in R will not seriously affect the estimation of Q. It should be noted that it takes a relatively long time of pumping to achieve a steady state in a well in an unconfined aquifer. The recovery after the cessation of pumping is also slow compared to the response of an artesian well which is relatively fast. Approximate Equations If the drawdown at the pumping well sw = (H – hw) is small relative to H, then H2 – h 2w = (H + hw) (H – hw) » 2 H sw Noting that T = KH, Eq. (9.50) can be written as 2 p T sw (9.50a) Q= ln R rw which is the same as Eq. (9.48). Similarly Eq. (9.49) can be written in terms of s1 = (H – h1) and s2 = (H – h2) as 2 p T ( s1 - s2 ) (9.49a) Q= r2 ln r1 Equations (949a) and (9.50a) are approximate equations to be used only when Eq. (9.49) or (9.50) cannot be used for lack of data. Equation (9.50a) over estimates the discharge by [1/2 (H/sw – 1)] % when compared to Eq. (9.50). EXAMPLE 9.8 A 30-cm well completely penetrates an unconfined aquifer of saturated depth 40 m. After a long period of pumping at a steady rate of 1500 lpm, the drawdown in two observation wells 25 and 75 m from the pumping well were found to be 3.5 and 2.0 m respectively. Determine the transmissivity of the aquifer. What is the drawdown at the pumping well? SOLUTION: (a)

Q=

1500 ´ 10-3 60

= 0.025 m3/s

h2 = 40.0 – 2.0 = 38.0 h1 = 40.0 – 3.5 = 36.5 m From Eq. (9.49), Q=

p K ( h22 - h12 ) ln

0.025 =

r2 = 75 m r1 = 25 m

r2 r1

p K [(38)2 - (36.5)2 ] ln

75 25

K = 7.823 ´ 10–5 m/s T = KH = 7.823 ´ 10–5 ´ 40 = 3.13 ´ 10–3 m2/s

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349

(b) At the pumping well, rw = 0.15 m Q=

p K ( H12 - hw2 ) ln

0.025 =

r1 rw

p ´ 7.823 ´ 10-5 [(36.5) 2 - hw2 ] ln

25 0.15

h2w = 811.84 and hw = 28.49 m Drawdown at the well, sw = 11.51m

9.9 OPEN WELLS Open wells (also known as dug wells) are extensively used for drinking water supply in rural communities and in small farming operations. They are best suited for shallow and low yielding aquifers. In hard rocks the cross sections are circular or rectangular in shape. They are generally sunk to a depth of about 10 m and are lined wherever loose over burden is encountered. The flow into the well is through joints, fissures and such other openings and is usually at the bottom/lower portions of the well. In unconsolidated formations (e.g. alluvial soils) the wells are usually dug to a depth of about 10 m below water table, circular in cross section and lined. The water entry into these wells is from the bottom. These wells tap water in unconfined aquifers. When the water in an open well is pumped out, the water level inside the well is lowered. The difference in the water table elevation and the water level inside the well is known as depression head. The flow discharge into the well (Q) is proportional to the depression head (H), and is expressed as Q = K0H (9.51) where the proportionality constant K0 depends on the characteristic of the aquifer and the area of the well. Also, since K0 represents discharge per unit drawdown it is called as specific capacity of the well. There is a critical depression head for a well beyond which any higher depression head would cause dislodging of soil particles by the high flow velocities. The discharge corresponding to the critical head is called as critical or maximum yield. Allowing a factor of safety (normally 2.5 to 3.0) a working head is specified and the corresponding yield from the well is known as safe yield. Recuperation Test The specific capacity K0 of a well is determined from the recuperation test described below. Let the well be pumped at a constant rate Q till a drawdown H 1 is obtained. The pump is now stopped and the well is allowed to recuperate. The water depth in the Fig. 9.18 Recuperation Test for Open well well is measured at various time intervals t starting from the stopping of the well. Referring to Fig. 9.18,

350 Engineering Hydrology H1 = drawdown at the start of recuperation, t = 0 H2 = drawdown at a time, t = Tr h = drawdown at any time t Dh = decrease in drawdown on time Dt At any time t, the flow into the well Q = K0h In a time interval Dt causing a small change Dh in the water level, Q × Dt = K0h × Dt = –A × Dh where A is the area of the well. In differential form A dh dt = – K0 h Integrating for a time interval Tr Tr

H2

dh A ò dt = – K ò h 0 H1 0

Tr =

K0

or The term

A

=

H1 A ln K0 H 2

(9.52)

H1 1 ln Tr H2

(9.52a)

K0

= Ks represents specific capacity per unit well area of the aquifer and A is essentially a property of the aquifer. Knowing H1, H2 and the recuperation time Tr for reaching H2 from H1, and the specific capacity per unit well area is calculated by Eq. (9.52a). Usually the Ks of an aquifer, determined by recuperation tests on one or more wells, is used in designing further dug wells in that aquifer. However, when such information is not available the following approximate values of Ks, given by Marriot, are often used. Type of sub-soil Clay Fine sand Coarse sand

Value of Ks in units of h–1 0.25 0.50 1.00

The yield Q from an open well under a depression head H is obtained as Q = Ks AH (9.5a) For dug wells with masonry sidewalls, it is usual to assume the flow is entirely from the bottom and as such A in Eq. (9.51a) represents the bottom area of the well. EXAMPLE 9.9 During the recuperation test of a 4.0 m open well a recuperation of the depression head from 2.5 m to 1.25 m was found to take place in 90 minutes. Determine the (i) specific capacity per unit well area and (ii) yield of the well for a safe drawdown of 2.5 m (iii) What would be the yield from a well of 5.0 m diameter for a drawdown of 2.25 m?

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351

p ´ (4.0) 2 = 12.566 m2 4 K0 H1 1 From Eq. (9.52a), = ln H2 A Tr Here Tr = 90 min = 1.50 h, H1 = 2.5 m, and H2 = 1.25 m K0 2.5 1 (i) Ks = = = 0.462 h–1 ln A 1.5 1.25 (ii) Q = Ks × A × H = 0.462 ´ 12.566 ´ 2.5 = 14.52 m3/h

SOLUTION: A =

p ´ (5.0) 2 = 19.635 4 Q = Ks ´ A2 ´ H2 = 0.462 ´ 19.635 ´ 2.25 = 20.415 m3/h

(iii) A2 =

9.10 UNSTEADY FLOW IN A CONFINED AQUIFER When a well in a confined aquifer starts discharging, the water from the aquifer is released resulting in the formation of a cone of depression of the piezometric surface. This cone gradually expands with time till an equilibrium is attained. The flow configuration from the start of pumping till the attainment of equilibrium is in unsteady regime and is described by Eq. (9.26). In polar coordinates, Eq. (9.26), to represent the radial flow into a well, takes the form

S ¶h ¶2 h 1 ¶h = (9.53) + T ¶t ¶r 2 r ¶r Making the same assumptions as used in the derivation of the equilibrium formula (Eq. 9.46), Thies (1935) obtained the solution of this equation as Q ¥ e- u du s = (H – h) = (9.54) ò 4p T u u where s = H – h = drawdown at a point distance r from the pumping well, H = initial constant piezometric head, Q = constant rate of discharge, T = transmissibility of the aquifer, u = a parameter = r2 S/4Tt, S = storage coefficient and t = time from start of pumping. The integral on the right hand side is called the well function, W (u), and is given by W(u) =

¥

e- u u2 u3 ò u du = –0.577216 – ln u + u – 2.2! + 3.3! . . . u

(9.55)

Table of W(u) are available in literature (e.g. Refs. 1, 9 and 10). Values of W(u) can be easily calculated by the series (Eq. 9.55) to the required number of significant digits which rarely exceed 4. For small values of u(u £ 0.01), only the first two terms of the series are adequate. The solution of Eq. (9.54) to find the drawdown s for a given S, T, r, t and Q can be obtained in a straightforward manner. However, the estimation of the aquifer constants S and T from the drawdown vs time data of a pumping well, which involve trial-and-error procedures, can be done either by a digital computer or by semigraphical methods such as the use of Type curve1, 8, 9 or by Chow’s method described in literature1.

352 Engineering Hydrology For small values of u (u £ 0.01), Jacob (1946, 1950) showed that the calculations can be considerably simplified by considering only the first two terms of the series of W(u), (Eq. 9.55). This assumption leads Eq. (9.54) to be expressed as Q é r2 S ù -0.5772 - ln s= ê 4p T ë 4 T t úû

Q 2.2 Tt ù (9.56) ln é 4 p T êë r 2 S úû If s1 and s2 are drawdowns at times t1 and t2, t2 Q (9.57) (s2 – s1) = ln t1 4p T If the drawdown s is plotted against time t on a semi-log paper, the plot will be a straight line for large values of time. The slope of this line enables the storage coefficient S to be determined. From Eq. (9.54), when s = 0, 2.25T t0 =1 r2 S 2.25T t0 or S= (9.58) r2 i.e.

s=

Fig. 9.19 Time – Drawdown Plot—Example 9.10

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353

in which t0 = time corresponding to “zero” drawdown obtained by extrapolating the straight-line portion of the semi-log curve of s vs t (Fig. 9.19). It is important to remember that the above approximate method proposed by Jacob assumes u to be very small. Drawdown Test Equations (9.56 and 9.57) relating drawdown s with time t and aquifer properties is used to evaluate formation constants S and T through pumping test. The method is known as drawdown test. Procedure: An observation well at a distance r from the production well is selected. The pumping is started and the discharge is maintained at a constant value (Q) throughout the test. Values of the drawdown s are read at the observation well at various times, t. The time intervals between successive readings could progressively increase to cut down on the number of observations. The pumping is continued till nearly steady state conditions are reached. This may take about 12 to 36 hours depending on the aquifer characteristics. The best values of S and T are obtained from Eqs. 9.56 and 9.57 through semi-log plot of s against time t. EXAMPLE 9.10 A 30-cm well penetrating a confined aquifer is pumped at a rate of a 1200 lpm. The drawdown at an observation well at a radial distance of 30 m is as follows: Time from start (min) Drawdown (m)

1.0 0.2

2.5 0.5

5 0.8

10 1.2

20 1.8

50 2.5

100 200 500 1000 3.0 3.7 4.4 5.0

Calculate the aquifer parameters S and T.

SOLUTION: The drawdown is plotted against time on a semilog plot (Fig. 9.19). It is seen that for t > 10 min. the drawdown values describe a straight line. A best-fitting straight line is drawn for data points with t > 10 min. From this line, when s = 0, t = t0 = 2.5 min = 150 s s1 = 3.1 m at t1 = 100 min s2 = 5.0 m at t2 = 1000 min Also, Q = 1200 lpm = 0.02 m2/s From Eq. (9.57) t2 Q ln s2 – s1 = t1 4pT 0.02 1000 (5.0 – 3.1) = ln 4 ´ p ´ T 100 T= From Eq. (9.58), S=

i.e.

0.02 ln 10 = 1.929 ´ 10–3 m3/s/m = 1.67 ´ 105 lpd/m 4 p ´ 1.9 2.25 T t0

r2 S = 7.23 ´ 10–4

=

2.25 ´ 1.929 ´ 10-3 ´ 150 (30)2

EXAMPLE 9.11 A well is located in a 25 m confined aquifer of permeability 30 m/day and storage coefficient 0.005. If the well is being pumped at the rate of 1750 lpm, calculate the drawdown at a distance of (a) 100 m and (b) 50 m from the well after 20 h of pumping.

354 Engineering Hydrology SOLUTION: (a)

T =KB= u=

30 ´ 25 = 8.68 ´ 10–3 m2/s 86400

(100) 2 ´ ( 0.005 ) r2 S = = 0.02 4T t 4 ´ (8.68 ´ 10-3 ) ´ (20 ´ 60 ´ 60)

Using Theis method and calculating W(u) to four significant digits, W(u) = –0.5772 – ln (0.02) + (0.02) –

(0.02)2 2.2!

+

(0.02)3 3.3!

= –0.5772 + 3.9120 + 0.02 – 0.0001 + 4.4 ´ 10–7 = 3.3547 S100 =

Q 4p T

W (u )

1 æ 1.750 ö ´ ´ 3.3547 = 0.897 m ÷ 60 ø 4 p (8.68 ´ 10-3 )

= ç è (b)

r = 50 m, u =

(50) 2 ´ (0.005) 4 ´ (8.68 ´ 10-3 ) ´ (20 ´ 60 ´ 60)

= 0.005

W(u) = – 0.5772 – ln 0.005 + 0.005 = 4.726

1 æ 1.750 ö ´ 4.726 = 1.264 m ÷´ 60 ø 4 p (8.68 ´ 10-3 )

S50 = ç è

(Note that for small values of u, i.e. u < 0.01, W(u) » – 0.5772 – ln u).

Recovery of Piezometric Head Consider a well pumped at constant rate of Q. Let s1 be the drawdown at an observation well near the well in time t1. If the pumping is stopped at the instant when the time is t1, the ground water flow into the cone of depression will continue at the same rate Q. Since there is not withdrawal now, the water level in the Fig. 9.20 Variation of Piezometric Head in Pumping and Recovery Head observation well will begin to rise and the drawdown will begin to decrease. This is known as the recovery of the cone of depression. The variation of the water level with time during pumping and in the recovery phase is shown in Fig. 9.20. The drawdown at the observation well at any time t ¢ after the cessation of the pumping is known as residual drawdown and can be calculated as

Groundwater

s¢ =

Q [ W ( u ) - W ( u ¢ )] 4p T

355 (9.59)

r2 S r2 S and u¢ = 4p T t 4p T t ¢ t = t1 + t¢ = time from start of pump and t¢ = time since stoppage of pumping (start of recovery). For small values of r and large values of t¢ Eq. (9.59) can be approximated as

where

u=

s¢ =

Q . t t 2.302 . Q . log = ln 4p T 4p T t¢ t¢

(9.60)

The plot of residual drawdown s¢ vs (t/t¢) on semi-log paper represents a straight line é 2.302 Q ù with its slope as ê ú. ë 4p T û Recovery Test The relationship of the residual recovery given by Eq. (9.60) is used as a method of assessing the transmissibility T of the aquifer. The procedure is known as Recovery test. In this test, the pump is run at constant discharge rate for a sufficiently long time t1, and then stopped. The value of t1 depends on the type of aquifer and aquifer characteristics and may range from 12 to 24 hours. The recovery of water level s¢ in an observation well situated at a distance r from the production well is noted down at various times (t¢). In view of the logarithmic nature of the variation of residual drawdown with the time ratio (t/t¢), the time intervals between successive readings could progressively increase, When observation wells are not available, the recovery water levels can be observed in the production well itself and this is a positive advantage of this test. The value of transmissibility T is calculated from plot of s¢ against (t/t¢) on semilog axes. It is to be noted that the recovery test data does not enable the determination of the storage coefficient S. EXAMPLE 9.12 Recovery test on a well in a confined aquifer yielded the following data: Pumping was at a uniform rate of 1200 m2/day and was stopped after 210 minutes of pumping. Recovery data was as shown below: Time since stoppage of pump (min) Residual drawdown (m)

2 5 10 20 40 90 150 210 0.70 0.55 0.45 0.30 0.25 0.19 0.15 0.10

SOLUTION: Here since t1 = 210 min, t = t1 + t¢ = 210 + t¢ The time ratio t/t¢ is calculated (as shown in the table below) and a semi-log plot of s¢ vs t/t¢ is plotted (Fig. 9.21). t¢ t t/t¢ s¢

2 212 106 0.70

5 215 43 0.55

10 220 22 0.45

20 240 11.5 0.30

40 250 6.25 0.25

90 300 3.33 0.19

150 360 2.40 0.15

210 420 2.0 0.10

356 Engineering Hydrology

Fig. 9.21 Plot of residual drawdown against time ratio (J/J¢)—Example 9.12 A best fitting straight line through the plotted points is given by the equation s¢ = 0.1461 ln (t/t¢) – 0.0027 Q By Eq. (9.60), Slope of best fit line = 0.1461 = 4p T 1200 T= = 654 m2/day 0.1461 ´ 4p

9.11 WELL LOSS In a pumping artesian well, the total drawdown at the well sw, can be considered to be made up of three parts: 1. Head drop required to cause laminar porous media flow, called formation loss, s wL (Fig. 9.22); 2. drop of piezoFig. 9.22 Definition Sketch for Well Loss metric head required to sustain turbulent flow in the region nearest to the well where the Reynolds number may be larger than unity, swt; and 3. head loss through the well screen and casing, swc. Of these three, swL µ Q and (swt and swc) µ Q2 2 thus sw = C1Q + C2Q (9.61) where C1 and C2 are constants for the given well (Fig. 9.21). While the first term C1Q is the formation loss the second terms C2Q2 is termed well loss. The magnitude of a well loss has an important bearing on the pump efficiency. Abnormally high value of well loss indicates clogging of well screens, etc. and requires

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357

immediate remedial action. The coefficients C1 and C2 are determined by pump test data of drawdown for various discharges.

9.12 SPECIFIC CAPACITY The discharge per unit drawdown at the well (Q/sw) is known as specific capacity of a well and is a measure of the performance of the well. For a well in a confined aquifer under equilibrium conditions and neglecting well losses, by Eq. (9.48). Q 2p T = i.e. Q/sw µ T ln R/rw sw However, for common case of a well discharging at a constant rate Q under unsteady drawdown conditions, the specific capacity is given by Q 1 = (9.62) sw 2.25 Tt 1 ln + C2 Q 4pT rw2 . S where t = time after the start of pumping. The term C2Q is to account for well loss. It can be seen that the specific capacity depends upon T, s, t, rw and Q. Further, for a given well it is not a constant but decreases with increases in Q and t.

9.13 RECHARGE Addition of surface water to zone of saturation is known as recharge. Recharge taking place naturally as a part of hydrologic cycle is called natural recharge while the process of increasing infiltration of surface water to groundwater systems by altering natural conditions is known as artificial recharge.

Natural Recharge The amount of precipitation that infiltrates into the soil and reaches the zone of saturation is an important component of natural recharge. Seepage from irrigated lands is another important component of recharge of groundwater. In this process the infiltration phase is natural while the supply of water to the irrigated lands is through artificial means and as such it is sometimes called as incidental recharge. Other means of natural recharge are seepage from reservoirs; rivers, streams and canals; and other water bodies. Estimation of recharge rates of aquifers is an important component of groundwater resource estimation and in proper utilization of groundwater.

Artificial Recharge The process of artificially enhancing the amount of water recharging the aquifer in a given location is known as artificial recharge. In the face of present-day large demands for groundwater artificial recharge is resorted to l Conserve runoff l Improve quantity of available groundwater l Reduce or correct saltwater intrusion. Various recharging methods commonly adopted are l Spreading [Flooding, Basin, Ditch, Pit & Channel] l Through injection wells l Induced recharge from surface water bodies

358 Engineering Hydrology l l

Subsurface dykes Percolation tanks, Check dams, Nala bunds and other watershed treatment methods.

Estimation of Recharge Groundwater Resource Estimation Committee11 (GEC-97) recommends two approaches to assessment of recharge to groundwater. These are (i) Groundwater level fluctuation method, and (ii) Rainfall infiltration factor method. (1) Groundwater Level Fluctuation and Specific Yield Method In this method the groundwater level fluctuations over a period (usually a monsoon season) is used along with the specific yield to calculate the increase in storage in the water balance equation. Thus for a given area of extent A (usually a watershed), for a water level fluctuation of h during a monsoon season, (9.63) h Sy A = RG – DG – B + Is + I where Sy = specific yield RG = gross recharge due to rainfall and other sources DG = gross water draft B = base flow into the stream from the area Is = recharge from the stream into the ground water body I = net ground water flow into the area across the boundary (i.e. inflow – outflow) Writing R = RG – B + I + Is Eq. 9.63 would be R = h Sy A – DG (9.64) where R = possible recharge, which is gross recharge minus the natural recharge of the area, and would consist of other recharge factors as R = Rrf + Rgw + Rwi + Rt (9.65) where Rrf = recharge from rainfall Rgw = recharge from irrigation in the area (includes both surface and ground water sources) Rwi = recharge from water conservation structures Rt = recharge from tanks and ponds Computations, using Eq. (9.63) through (9.65) are usually based on the monsoon season rainfall and corresponding groundwater fluctuation covering a span of 30 to 50 years to obtain normal monsoon recharge due to rainfall. The recharge in non-monsoon months is taken as zero if rainfall in non-monsoon months is less than 10% of normal annual rainfall. The computation for calculating the total annual recharge is carried out for both monsoon months and non-monsoon months and the total annual recharge is obtained as a sum of these two. The specific yield for various hydrogeologic conditions in the country is estimated through norms given in Table 9.5. (2) Rainfall Infiltration Method In areas where ground water level monitoring is not adequate in space and time, rainfall infiltration method may be used. The recharge from rainfall in monsoon season is taken as a percentage of normal monsoon rainfall in the area.

359

Groundwater

Thus where

Rrf = f A Pnm Rrf = recharge from rainfall in monsoon season f = rainfall infiltration factor Pnm = normal rainfall in monsoon season A = area of computation for reacharge.

(9.66)

Table 9.5 Norms for Specific Yield (5O in percentage) No.

Description of the area

1

Alluvial areas Sandy alluvium Silty alluvium Clayey alluvium Hard Rock Areas Weathered granite, gneiss and schist · with low clay content · with significant clay content Weathered or vesicular, jointed basalt Laterite Sandstone Quartzite Limestone Karstified limestone Phyllites, Shales Massive, poorly fractured rock

2

Recommended Minimum Maximum value value value 16 10 6

12 8 4

20 12 8

3.0 1.5 2.0 2.5 3.0 1.5 2.0 8.0 1.5 0.3

2.0 1.0 1.0 2.0 1.0 1.0 1.0 5.0 1.0 0.2

4.0 2.0 3.0 3.0 5.0 2.0 3.0 15.0 2.0 0.5

The norms for the rainfall factor f for various hydrogeological situations in the country are given in the following table. Table 9.6 Norms for Selection of Rainfall Factor B No. Area

Value of f in percentage Recommended Minimum value value

1

2

Alluvial areas l Indo-Gangetic and inland areas l East coast l West coast Hard Rock Areas l Weathered granite, gneiss and schist with low clay content l Weathered granite, gneiss and schist with significant clay content l Granulite facies like charnokite etc. l Vesicular and jointed basalt

Maximum value

22 16 10

20 20 8

25 18 12

11

10

12

8

5

9

5 8

4 5

6 9 (Contd.)

360 Engineering Hydrology (Contd.) l l l l

l l

Weathered basalt Laterite Semi-consolidated sand stone Consolidated sand stone, quartzite, limestone (except cavernous limestone) Phyllites, Shales Massive poorly fractured rocks

5 13 7

4 12 6

6 14 8

7 12 6

6 10 5

8 14 7

The same factors are used for non-monsoon months also with the condition that the recharge is taken as zero if the normal rainfall in non-monsoon season is less than 10% of normal annual rainfall. Recharge from sources other than rainfall are also estimated by using appropriate factors (e.g., Tables 9.7, 9.8 and 9.9). The total recharge is obtained as the sum of recharge from rainfall and recharge from other sources. Recharge due to Seepage from Canals When actual specific values are not available, the following norms may be adopted: Table 9.7 Recharge due to Seepage from Canals 1

Unlined canals in sandy soils with some silt content

2

Unlined canals in normal soils with some silt content

3

Lines canals and canals in hard rock areas

· · · · · · · · ·

1.8 to 2.5 cumec/million sq.m of wetted area or 15–20 ha.m/day/million sq. m of wetted area 3 to 3.5 cumec/million sq. m of wetted area or 25–30 ha.m/day/million sq. m of wetted area 20% of above values for unlined canals

Recharge from Irrigation The recharge due to flow from irrigation may be estimated, based on the source of irrigation (ground water or surface water), the type of crop and the depth of water table below ground level through the use of normal given below: Table 9.8 Recharge from Irrigation Source of Irrigation

Type of Crop

Recharge as percentage application Water table below Ground level < 10 m

Ground water Surface water Ground water Surface water

Non-paddy Non-paddy Paddy Paddy

25 30 45 50

10–25 m 15 20 35 40

> 25 m 5 10 20 25

Recharge from Water Harvesting Structures The following norms are commonly followed in the estimation of recharge from water harvesting structures:

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Table 9.9 Recharge factors for Tanks and other Water Harvesting Structures S. No.

Structure

1

Recharge from Storage Tanks/ Ponds

2

Recharge from Percolation Tanks

3

Recharge due to Check dams and Nala bunds.

Recharge Factor 1.4 mm/day for the period in which the tank has water, based on the average area of water spread. If the data on average water spread is not available, 60% of the maximum water spread area may be used. 50% of gross storage, considering the number of fillings. Half this value of recharge is assumed to be occurring during monsoon season. 50% of gross storage. Half the value of recharge is assumed to be occurring during monsoon season.

Detailed procedure for the estimation of Groundwater resources of an area under Indian conditions available in Ref. 11.

9.14 GROUNDWATER RESOURCE The quantum of groundwater available in a basin is dependent on the inflows and discharges at various points. The interrelationship between inflows, outflows and accumulation is expressed by the water budget equation S I Dt – S Q Dt = DS (9.67) where S I Dt represents all forms of recharge and includes contribution by precipitation; infiltration from lakes, streams and canals; and artificial recharge, if any, in the basin. S Q Dt represents the net discharge of groundwater from the basin and includes pumping, surface outflows, seepage into lakes and rivers and evapotrans-piration. DS indicates the change in the groundwater storage in the basin over a time Dt. Considering a sufficiently long time interval, Dt of the order of a year, the capability of the groundwater storage to yield the desired demand and its consequences can be estimated. It is obvious that too large a withdrawal than what can be replenished naturally leads ultimately to the permanent lowering of the groundwater table. This in turn leads to problems such as drying up of open wells and surface storages like swamps and ponds and change in the characteristics of vegetation that can be supported by the basin. Similarly, too much of recharge and scanty withdrawal or drainage leads to waterlogging and consequent decrease in the productivity of lands. The maximum rate at which the withdrawal of groundwater in a basin can be carried without producing undesirable results is termed safe yield. This is a general term whose implication depends on the desired objective. The “undesirable” results include (i) permanent lowering of the groundwater table or piezometric head, (ii) maximum drawdown exceeding a preset limit leading to inefficient operation of wells, and (iii) salt-water encroachment in a coastal aquifer. Depending upon what undesirable effect is to be avoided, a safe yield for a basin can be identified. The permanent withdrawal of groundwater from storage is known as mining as it connotes a depletion of a resource in a manner similar to the exploitation of mineral resource. The total groundwater resource of a region can be visualized as being made up of two components: Dynamic resource and Static resource. The dynamic resource

362 Engineering Hydrology represents the safe yield, which is essentially the annual recharge less the un-avoidable natural discharge. The static resource is the groundwater storage available in the pores of the aquifer and its exploitation by mining leads to permanent depletion. Generally the static resource is many times larger than the dynamic resource. However, mining is resorted to only in case of emergencies such as droughts etc. and in exceptional cases of planned water resources development. In essence, it is a resource to be used in emergency. As such, the utilisable groundwater resource of a region is the safe yield at a given state of development. It is often said, in a general sense, that the water resource is a replenishable resource. So far as the groundwater resource is concerned, only the dynamic component is replenishable and the static component is non-replenishable. The annual utilisable groundwater resource of a region is computed by using the water budget method. The total annual recharge is made up of: l rainfall recharge l seepage from canals l deep percolation from irrigated areas l inflow from influent streams etc. l recharge from tanks, lakes, submerged lands, and l artificial recharge schemes, if any. The groundwater losses from aquifers occur due to l outflow to rivers l transpiration by trees and other vegetation l evaporation from the water table The difference between the enumerated annual recharges and the losses as above is the annual groundwater resource which is available for irrigation, domestic and industrial uses. It should be noted that with the growth in the expansion of canal irrigation the groundwater resources also grow. Further, increase in the recharge of surface waters through artificial methods would also enhance the groundwater resources. The National water policy (1987) stipulates: l Exploitation of the groundwater resources should be so regulated as not to exceed the recharging possibilities, as also to ensure social equity. Groundwater recharge projects should be developed and implemented for augmenting the available supplies. l There should be periodical reassessment on a scientific basis of the groundwater resources taking into consideration the quality of the water available and economic viability.

Categories of Groundwater Development The groundwater development in areas are categorized as safe, semi-critical and critical based on the stage of groundwater development and long-term trend of pre and post-monsoon groundwater levels. Category

% of groundwater development

Long term decline of pre & postmonsoon groundwater levels

Safe Semi-critical Critical Over exploited

< 70% 70% to 90% 90% to 100% > 100%

Not significant Significant Significant Significant

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363

Groundwater Resources of India The National Commission on Agriculture (1976) estimated the groundwater resources at 350 km3, of which 260 km3 was available for irrigation. The groundwater over exploitation committee (1979) estimated the groundwater potential as 467.9 km3. The Groundwater estimation committee (1984) suggested a suitable methodology for estimation of groundwater. Using these norms CGWB (1955) has estimated the total replenishable groundwater potential of the country (dynamic) at 431.89 km3. The statewise and basinwise estimates of dynamic groundwater (fresh) resource made by CGWB (1995) are given in Tables 9.10 and 9.11. Table 9.10 State-wise Dynamic Fresh Groundwater Resource S. No. States

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26

Andhra Pradesh Arunachal Pradesh Assam Bihar Goa Gujarat Haryana Himachal Pradesh Jammu and Kashmir Karnataka Kerala Madhya Pradesh Maharashtra Manipur Meghalaya Mizoram Nagaland Orissa Punjab Rajasthan Sikkim Tamil Nadu Tripura Uttar Pradesh West Bengal Union Territories Total

[Source: Ref. 12]

Total Replenishable Groundwater Resource from Normal Natural Recharge

Total Replenishable Groundwater Resource due to Recharge Augmentation from Canal Irrigation

Total Replenishable Groundwater Resource

Km3 per year

Km3 per year

Km3 per year

20.03 1.44 24.23 28.31 0.18 16.38 4.73 0.29 2.43 14.18 6.63 45.29 33.40 3.15 0.54 0.72 16.49 9.47 10.98 18.91 0.57 63.43 20.30 0.35 342.43

15.26 0.00 0.49 5.21 0.03 4.00 3.80 0.28 2.00 2.01 1.27 5.60 4.47 0.00 0.00 Not Assessed 0.00 3.52 9.19 1.72 Not Assessed 7.48 0.10 20.39 2.79 0.05 89.46

35.29 1.44 24.72 33.52 0.21 20.38 8.53 .037 4.43 16.19 7.90 50.89 37.87 3.15 0.54 0.72 20.01 18.66 12.70 26.39 0.67 83.82 23.09 0.40 431.89

364 Engineering Hydrology Table 9.11 Basinwise Dynamic Fresh Groundwater Resource12 (Unit: km3/year) S. No. River Basin

1 2

3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24

Indus Ganga-BrahmaputraMeghna Basin 2a Ganga sub-basin 2b Brahmaputra sub-basin and 2c Meghna (Barak) sub-basin Subarnarekha Brahmani-Baitarani Mahanadi Godavari Krishna Pennar Cauvery Tapi Narmada Mahi Sabarmati West flowing rivers of Kutchch and Saurashtra West flowing rivers south of Tapi West flowing rivers between Mahanadi and Godavari East flowing rivers between Godavari and Krishna East flowing rivers between Krishna and Pennar East flowing rivers between Pennar and Cauvery East flowing rivers south of Cauvery Area North of Ladakh no draining into India Rivers draining into Bangladesh Rivers draining into Myanmar Drainage areas of Andaman, Nicobar and Lakshadweep islands Total

Total Replenishable Groundwater Resource from Normal Natural Recharge

Total Replenishable Groundwater Resource due to Recharge Augmentation from Canal Irrigation

14.29

12.21

26.50

136.47 25.72

35.10 0.83

171.57 26.55

8.52 1.68 3.35 13.64 33.48 19.88 4.04 8.79 6.67 9.38 3.50 2.90

0.00 0.12 0.70 2.86 7.12 6.52 0.89 3.51 1.6 1.42 0.50 0.30

8.52 1.80 4.05 16.50 40.60 26.40 4.93 12.30 8.27 10.80 4.00 3.20

9.10

2.10

11.20

17.70

2.15

15.55

[5.98]

[18.80]

[5.55]

[12.65]

ü ï ï ý [12.82] ï ï þ ü ï [18.20] ý ïþ

Total Replenishable Groundwater Resource

Not Assessed Not Assessed Not Assessed

342.43

Not Assessed 89.46

431.89

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365

It is seen from Tables 9.10 and 9.11 though the rainfall is the principal source of recharge, the contribution of canal seepage and irrigation return flows has also been significant in some states. The contributions are more than 40% in states of Punjab, Haryana, J&K and Andhra Pradesh. Groundwater extraction by individuals, organizations and local bodies has become a common phenomenon. Consequently, there is considerable development and utilization of available groundwater sources. Further, the level of extraction has reached critical or over-exploitation level in several pockets in many states. Table 9.12 gives a list of states with considerable exploitation groundwater resources. Table 9.12 States with more than 40% Groundwater Development12 State Punjab Haryana Rajasthan Tamil Nadu Gujarat

Percent area over-exploited

Level of Groundwater development

52 42 19 14 6

94 84 51 61 42

Utilizable Groundwater Resources As seen from Table 9.10 or 9.11, the sum total of potential for natural recharge from rainfall and due to recharge augmentation from canal irrigation system in the country 431.9 km3/year. The utilizable groundwater potential is calculated as 396 km3/year as below: 1. Total replenishable groundwater potential = 432 km3/year 2. Provision for domestic drinking water and other uses @ 15% of item 1 = 71 km3/year 3. Utilizable groundwater resource for irrigation @ 90% of (item 1 – item 2) = 325 km3/year 4. Total utilizable dynamic groundwater resource (Sum of items 2 and 3) = 396 km3/year

9.15

GROUNDWATER MONITORING NETWORK IN INDIA

The Central Groundwater Board monitors the ground water levels from a network of about 15000 stations (mostly dug wells selected from existing dug wells evenly distributed throughout in the country). Dug wells are being replaced by piezometers for water level monitoring. Measurements of water levels are taken at these stations four times in a year in the months of January, April/May, August and November. The groundwater samples are also collected during April/May measurements for chemicals analyses every year. The data so generated are used to prepare maps of groundwater level depths, water level contours and changes in water levels during different periods and years. Deeper groundwater level of over 50 metres is observed in Peidmont aquifer in Bhabar belt in foot hills of Himalayas. In Western Rajasthan ground water levels have depths ranging from 20 to 100 metres. In peninsular region, water levels range from 5 to 20 metres below land surface.

366 Engineering Hydrology

REFERENCES 1. Bauwer, H., Groundwater Hydrology. McGraw-Hill’ Kogakusha, Tokyo, 1978. 2. Bear, J., Hydraulics of Groundwater, McGraw-Hill, New York, 1979. 3. Central Water Commission, Water Resources of India, CWC Pub. No. 30/88, April 1988, CWC, New Delhi, India. 4. Davis, S.N. and R.J. M. DeWiest, Hydrogeology, John Wiley and Sons; New York, 1966. 5. Halek, V. and J. Svec, Groundwater Hydraulics, Elsevier, Amsterdam, 1979. 6. Marino, M.A. and J.N. Luthin, Seepage and Groundwater, Elsevier; Amsterdam, 1982. 7. Polubarinova Kochina, P.Y., Theory of Groundwater Movement, English Trans. by R.J.M. Dewiest, Princeton Univ. Press, Princeton, 1962. 8. Taylor, D.W., Fundamentals of Soil Mechanics, John Wiley and Sons, New York, 1956. 9. Todd, D.K., Groundwater Hydrology, John Wiley and Sons, New York, 1958, 10. Walton, W.C., Groundwater Resource Evaluation, McGraw-Hill, Kogakusha, Tokyo, 1970. 11. Ministry of Water Resources, GOI, Report of the Groundwater Resources Estimation Committee, Groundwater Resource Estimation Methodology, New Delhi, June 1997. 12. Min. of Water Resources, GOI, Report of the National Commission for Integrated Water Resources Development, Vol. 1, New Delhi, Sept. 1999.

REVISION QUESTIONS 9.1 9.2

9.3 9.4 9.5 9.6 9.7

Explain briefly the following terms as used in groundwater flow studies (a) Specific yield (b) Storage coefficient (c) Specific capacity (d) Barometric efficiency Distinguish between (a) Aquifer and aquitard (b) Unconfined aquifer and a leaky aquifer (c) Influent and effluent streams (d) Water table and piezometric surface (e) Specific capacity of a well and the specific yield of an aquifer Explain the following (a) Perched water table (b) Intrinsic permeability (c) Bulk pore velocity (d) Well loss (e) Recharge Discuss the geological formations in India which have potential as aquifers. Explain the behaviour of water level in wells in confined aquifers due to changes in the atmospheric pressure. Develop the equation relating the steady state discharge from a well in an unconfined aquifer and depths of water table at two known positions from the well. State clearly all the assumptions involved in your derivation. What are Dupit’s assumptions? Starting from an elementary prism of fluid bounded by a water table, show that for the steady one-dimensional unconfined groundwater flow with a recharge rate R, the basic differential equation is ¶2 h

2R = K ¶x 2 where K = permeability of the porous medium. 9.8 Sketch a typical infiltration gallery. Calculate the discharge per unit length of the infiltration gallery by making suitable assumptions. State clearly the assumptions made. 9.9 Derive the basic differential equation of unsteady groundwater flow in a confined aquifer. State clearly the assumptions involved. 9.10 Describe a procedure by using Jacob’s method to calculate the aquifer parameters of a confined aquifer by using the well pumping test data. 9.11 Describe the recovery test to estimate the transmissivity of a confined aquifer. 9.12 The aquifer properties S and T of a confined aquifer in which a well is driven are known. Explain a procedure to calculate the drawdown at a location away from the well at any instant of time after the pump has started.

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367

9.13 Explain briefly (a) Safe yield of an aquifer (b) Mining of water (c) Recharge estimation (d) Groundwater estimation 9.14 Discuss the principle of recuperation test of an open well. 9.15 What are the commonly used methods to assess the recharge of groundwater in an area? Explain briefly any one of the methods. 9.16 Describe the groundwater resources of india and its utilization.

PROBLEMS 9.1 In a laboratory test of an aquifer material a fully saturated sample of volume 5 litres was taken and its initial weight of 105 N was recorded. When allowed to drain completely it recorded a weight of 97 N. The sample was then crushed, dried and then weighed. A weight of 93 N was recorded at this stage. Calculate the specific yield and relative density of the solids. (Assume unit weight of water g = 9.79 kN/m3) 9.2 A confined aquifer is 25 m thick and 2 km wide. Two observation wells located 2 km apart in the direction of flow indicate heads of 45 and 39.5 m. If the coefficient of permeability of the aquifer is 30 m/day, calculate (a) the total daily flow through the aquifer and (b) the piezometric head at an observation well located 300 m from the upstream well. 9.3 In a field test a time of 6 h was required for a tracer to travel between two observation wells 42 m apart. If the difference in water-table elevations in these wells were 0.85 m and the porosity of the aquifer is 20% calculate the coefficient of permeability of the aquifer. 9.4 A confined aquifer has a thickness of 30 m and a porosity of 32%. If the bulk modulus of elasticity of water and the formation material are 2.2 ´ 105 and 7800 N/cm2 respectively, calcuate (a) the storage coefficient, and (b) the barometric efficiency of the aquifer. 9.5 An extensive aquifer is known to have a groundwater flow in N 30° E direction. Three wells A, B and C are drilled to tap this aquifer. The well B is to East of A and the well C is to North of A. The following are the data regarding these wells: Distance (m)

Well

Ground surface elevation (m above datum)

Water table elevation (m above datum)

AB = 800 m AC = 2000 m

A B C

160.00 159.00 158.00

157.00 156.50 ?

Estimate the elevation of water table at well C when the wells are not pumping. 9.6 A confined stratified aquifer has a total thickness of 12 m and is made up of three layers. The bottom layer has a coefficient of permeability of 30 m/day and a thickness of 5.0 m. The middle and top layers have permeability of 20 m/day and 45 m/day respectively and are of equal thickness. Calculate the transmissivity of the confined aquifer and the equivalent permeability, if the flow is along the stratification. 9.7 A pipe of 1.2 m diameter was provided in a reservoir to act as an outlet. Due to disuse, it was buried and completely clogged up for some length by sediment. Measurements indicated the presence of fine sand (K1 = 10 m/day) deposit for a length of 100 m, at the upstream end and of coarse sand (K2 = 50 m/day) at the downstream end for a length of 50 m. In between these two layers the presence of silty sand (K3 = 0.10 m/day) for some length is identified. For a head difference of 20 m on either side of the clogged length the seepage discharge is found to be 0.8 m3/day. Estimate the length of the pipe filled up by silty sand.

368 Engineering Hydrology 9.8

9.9

A confined horizontal aquifer of thickness 15 m and permeability K = 20 m/day, connects two reservoirs M and N situated 1.5 km apart. The elevations of the water surface in reservoirs M and N measured from the top of the aquifer, are 30.00 m and 10.00 m respectively. If the reservoir M is polluted by a contaminant suddenly, how long will it take the contaminant to reach the reservoir N? Assume the porosity of the aquifer n = 0.30. An Infiltration gallery taps an unconfined aquifer (K = 50 m/day) situated over a horizontal impervious bed (Fig. 9.23). For the flow conditions shown, estimate the discharge collected per unit length of the gallery.

Fig. 9.23 Schematic Layout of Problem 9.9 9.10 An unconfined aquifer has infiltration of irrigation water at a uniform rate R at the ground surface. Two open ditches, as shown in Fig. 9.24, keep the water table in equilibrium. Show that the spacing L of the drains is related as 4K 2 [ hm – h02 + 2 D ( hm - h0 )] L2 = R where K = coefficient of permeability of the aquifer. Neglect the width of drains. [Note: This relation is known as Hooghoudt’s equation for either open ditch or subsurface drains. When h0 = 0 and D = 0, this equation reduces to Eq. (9.44).]

Fig. 9.24 Seepage to open ditches—Problem 9.10

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369

9.11 A canal and a stream run paralIel to each other at a separation distance of 400 m. Both of them completely penetrate an unconfined aquifer (K = 3.0 m/day) located above a horizontal impervious bed. The aquifer forms the separation land mass between the two water bodies. The water surface elevations in the canal and the stream are 5.0 m and 3.0 m, the datum being the top of the horizontal impervious layer. Estimate (a) the uniform infiltration rate that will create a water table divide at a distance of 100 m from the canal. (b) the elevation of the water table divide and (c) the seepage discharges into the two water bodies. 9.12 Two rivers A and B run parallel to each other and fully penetrate the unconfined aquifer situated on a horizontal impervious base. The rivers are 4.0 km apart and the aquifer has a permeability of 1.5 m/day. In an year, the average water surface elevations of the rivers A and B, measured above the horizontal impermeable bed, are 12.00 m and 9.00 m respectively. If the region between the rivers received an annual net infiltration of 20 cm in that year, estimate (a) the location of the groundwater table divide and (b) the average daily groundwater discharge into the rivers A and B from the aquifer between them. 9.13 A 30-cm well completely penetrates an artesian aquifer. The length of the strainer is 25 m. Determine the discharge from the well when the drawdown at the pumping well is 4.0 m. The coefficient of permeability of the aquifer is 45 m/day. Assume the radius of influence of the well as 350 m. 9.14 A 20-cm dia tubewell taps an artesian aquifer. Find the yield for a drawdown of 3.0 m at the well. The length of the strainer is 30 m and the coefficient of permeability of the aquifer is 35 m/day. Assume the radius of influence as 300 m. If all other conditions remain same, find the percentage change in yield under the following cases: (a) The diameter of the well is 40 cm; (b) the drawdown is 6.0 m; (c) the permeability is 17.5 m/day. 9.15 The discharge from a fully penetrating well operating under steady state in a confined aquifer of 35 m thickness is 2000 lpm. Values of drawdown at two observation wells 12 and 120 m away from the well are 3.0 and 0.30 m respectively. Determine the permeability of the aquifer. 9.16 A confined aquifer of thickness B has a fully penetrating well of radius of r0, pumping a discharge Q at a steady rate. An observation well M is located at a distance R from the pumping well. Show that the travel time for water to travel from well M to the pumping well is p Bh 2 t= ( R - r02 ) where h = Porosity of the aquifer. Q 9.17 A 45-cm well penetrates an unconfined aquifer of saturated thickness 30 m completely. Under a steady pumping rate for a long time the drawdowns at two observation wells 15 and 30 m from the well are 5.0 and 4.2 m respectively. If the permeability of the aquifer is 20 m/day, determine the discharge and the drawdown at the pumping well. 9.18 A 30-cm well fully penetrates an unconfined aquifer of saturated depth 25 m. When a discharge of 2100 lpm was being pumped for a long time, observation wells at radial distances of 30 and 90 m indicated drawdown of 5 and 4 m respectively. Estimate the coefficient of permeability and transmissibility of the aquifer. What is the drawdown at the pumping well? 9.19 For conducting tests on a 30 cm diameter well in an unconfined aquifer two observation wells A and B are bored at distances 25 m and 40 m respectively from the centre of the pumping well. When water is pumped at a rate of 10 litres/s the water depth in the pumping well is 10.0 m above the horizontal impervious layer up to which the well is driven. The median grain size of the aquifer is 2.5 mm and the permeability is known to

370 Engineering Hydrology

9.20

9.21

9.22

9.23

be 0.1 cm/s. Calculate (a) the depth of water above the impervious layer in the observation wells A and B; (b) the Reynolds number of flow at the pumping well and observation wells A and B. [Assume kinematic viscosity of water = 0.01 cm2/s]. A 45-cm well in an unconfined aquifer of saturated thickness of 45 m yields 600 lpm under a drawdown of 3.0 m at the pumping well, (a) What will be the discharge under a drawdown of 6.0 m? (b) What will be the discharge in a 30-cm well under a drawdown of 3.0 m? Assume the radius of influence to remain constant at 500 m in both cases. For conducting permeability tests in a well penetrating an unconfined aquifer, two observation wells A and B are located at distances 15 and 30 m respectively from the centre of the well. When the well is pumped at a rate of 5 lps, it is observed that the elevations of the water table above the impervious layer, up to which the well extends are 12.0 and 12.5 m respectively at A and B. Calculate the permeability of the aquifer in m/day. Calculate the discharge in m3/day from a tubewell under the following conditions: Diameter of the well = 45 cm Drawdown at the well = 12 m Length of strainer = 30 m Radius of influence of the well = 200 m Coefficient of permeability = 0.01 cm/s Aquifer = unconfined A fully penerating well of 30-cm diameter in an unconfined aquifer of saturated thickness 50 m was found to give the following drawdown-discharge relations under equilibrium condition. Drawdown at the pumping well (m) 3.0 11.7

Discharge (lpm) 600 1800

If the radius of influence of the well can be assumed to be proportional to the discharge through the well, estimate the flow rate when the drawdown at the well is 6.0 m. 9.24 A 45-cm well in an unconfined aquifer was pumped at a constant rate of 1500 lpm. At the equilibrium stage the following drawdown values at two observation wells were noted: Observation

Radial distance from pumping well (m)

Drawdown (m)

A B

10 30

5.0 2.0

The saturated thickness of the aquifer is 45 m. Assuming the radius of influence to be proportional to the discharge in the pumping well, calculate: (a) Drawdown at the pumping well; (b) transmissibility of the aquifer; (c) drawdown at the pumping well for a discharge of 2000 lpm; and (d) radius of influence for discharges of 1500 and 2000 lpm. 9.25 A 4.5 m diameter open well has a discharge of 30.0 m3/h with a drawdown of 2.0 m. Estimate the (i) specific capacity per unit well area of the aquifer and (ii) discharge from a 5.0 m open well in this aquifer under a depression head of 2.5 m. 9.26 In a recuperation test of a 3.0 m diameter open well the water level changed from Elevation 114.60 m to 115.70 m in 120 minutes. If the water table elevation is 117.00 m, diameter (i) the specific capacity per unit well area of the aquifer and (ii) discharge in the well under a safe drawdown of 2.75 m. 9.27 During a recuperation test, the water in an open well as depressed by pumping by 2.5 m it recuperated 1.8 m in 80 minutes. Calculate the yield from a well of 4.0 m diamater under a depression heat of 3.0 m.

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371

9.28 The drawdown time data recorded at an observation well situated at a distance of 50 m from the pumping well is given below: Time (min) Drawdown (m)

9.29

9.30

9.31 9.32

9.33

1.5 0.15

3 0.6

4.5 1.0

6 1.4

10 2.4

20 3.7

40 5.1

100 6.9

If the well discharge is 1800 lpm, calculate the transmissibility and storage coefficients of the aquifer. Estimate the discharge of a well pumping water from a confined aquifer of thickness 20 m with the following data: Distance of observation well from the pumping well = 100 m Drawdown at the observation well after 4 hours of pumping = 1.5 m Drawdown at the observation well after 16 hours of pumping = 2.0 m Storage coefficient, S = 0.0003 A fully penetrating well in a confined aquifer is being pumped at a constant rate of 2000 Lpm. The aquifer is known to have a storage coefficient of 0.005 and transmissibility of 480 m2/day. Find the drawdown at a distance of 3.0 m from the production well after (i) one hour and (ii) 8 hours after pumping. A fully penetrating well in a confined aquifer is pumped at the rate of 60 m3/h from an aquifer of storage coefficient and transmissibility 4 ´ 10–4 and 15 m2/h respectively. Estimate the drawdown at a distance of 100 m after 8 hours of pumping. A fully penetrating confined aquifer is pumped at a constant rate of 100 m3/h. At an observation well located at 100 m from the pumping well the drawdown where observed to be 0.65 m and 0.80 m after one and two hours of pumping respectively. Estimate the formation constants of the aquifier. A well in a confined aquifer was pumping a discharge of 40 m3/hour at uniform rate. The pump was stopped after 300 minutes of running and the recovery of drawdown was measured. The recovery data is shown below. Estimate the transmissibility of the aquifer. Time since stopping of the pump (min) Residual drawdown (m)

1 3 5 10 20 40 90 150 200 1.35 1.18 1.11 1.05 0.98 0.88 0.80 0.70 0.68

OBJECTIVE QUESTIONS 9.1 A geological formation which is essentially impermeable for flow of water even though it may contain water in its pores is called (a) aquifer (b) aquifuge (c) aquitard (d) aquiclude 9.2 An aquifer confined at the bottom but not at the top is called (a) Semiconfined aquifer (b) unconfined aquifer (c) confined aquifer (d) perched aquifer 9.3 A stream that provides water to the water table is termed (a) affluent (b) influent (c) ephemeral (d) effluent 9.4 The surface joining the static water levels in several wells penertating a confined aquifer represents (a) water-table surface (b) capillary fringe (c) piezometric surface of the aquifer (d) cone of depression. 9.5 Flowing artesian wells are expected in areas where (a) the water table is very close to the land surface (b) the aquifer is confined (c) the elevation of the piezometric head line is above the elevation of the ground surface (d) the rainfall is intense

372 Engineering Hydrology 9.6 9.7

9.8

9.9

9.10 9.11

9.12

9.13 9.14

9.15 9.16 9.17 9.18

Water present in artesian aquifers is usually (a) at sub atmospheric pressure (b) at atmospheric pressure (c) at 0.5 times the atmospheric pressure (d) above atmospheric pressure The volume of water that can be extracted by force of gravity from a unit volume of aquifer material is called (a) specific retention (b) specific yield (c) specific storage (d) specific capacity Which of the pairs of terms used in groundwater hydrology are not synonymous? (a) Permeability and hydraulic conductivity (b) Storage coefficient and storativity (c) Actual velocity of flow and discharge velocity (d) Water table aquifer and unconfined aquifer The permeability of a soil sample at the standard temperature of 20°C was 0.01 cm/s. The permeability of the same material at a flow temperature of 10° C is in cm/s (a) < 0.01 (b) > 0.01 (c) = 0.01 (d) depends upon the porous material A soil has a coefficient of permeability of 0.51 cm/s. If the kinematic viscosity of water is 0.009 cm2/s, the intrinsic permeability in darcys is about (a) 5.3 ´ 104 (b) 474 (c) 4.7 ´ 107 (d) 4000 Darcy’s law is valid in a porous media flow if the Reynolds number is less than unity. This Reynolds number is defined as (a) (discharge velocity ´ maximum grain size)/m (b) (actual velocity ´ average grain size)/n (c) (discharge velocity ´ average grain size)/n (d) (discharge velocity ´ pore size)/n Two observation wells penetrating into a confined aquifer are located 1.5 km apart in the direction of flow. Heads of 45 m and 20 m are indicated at these two observation wells. If the coefficient of permeability of the aquifer is 30 m/day and the porosity is 0.25, the time of travel of an inert tracer from one well to another is about (a) 417 days (b) 500 days (c) 750 days (d) 3000 days A sand sample was found to have a porosity of 40%. For an aquifer of this material, the specific yield is (a) = 40% (b) > 40% (c) < 40% (d) dependent on the clay fraction An unconfined aquifer of porosity 35%, permeability 35 m/day and specific yield of 0.15 has an area of 100 km2. The water table falls by 0.20 m during a drought. The volume of water lost from storage in Mm3 is (a) 7.0 (b) 3.0 (c) 4.0 (d) 18.0 The unit of intrinsic permeability is (a) cm/day (b) m/day (c) darcy/day (d) cm2 The dimensions of the storage coefficient S are (a) L3 (b) LT –1 (c) L3/T (d) dimensionless The dimensions of the coefficient of transmissibility T are (a) L2/T (b) L3T 2 (c) L/T 2 (d) dimensionless The coefficient of permeability of a sample of aquifer material is found to be 5 m/day in a laboratory test conducted with water at 10°C. If the kinematic viscosity of water at various temperatures is as below: Temp in °C v(m2/s)

10 1.30 ´ 106

20 1.00 ´ 106

30 0.80 ´ 106

the standard value of the coefficient of permeability of the material, in m/day, is about (a) 4.0 (b) 5.0 (c) 6.5 (d) 9.0

Groundwater

373

9.19 A stratified unconfined aquifer has three horizontal layers as below Layer

Coefficient of permeability (m/day)

Depth (m)

1 2 3

6 16 24

2.0 4.0 3.0

The effective vertical coefficient of permeability of this aquifer, in m/day, is about (a) 13 (b) 15 (c) 24 (d) 16 9.20 An aquifer confined at top and bottom by impervious layers is stratified into three layers as follows: Layer Top layer Middle layer Bottom layer

9.21 9.22

9.23

9.24

9.25

9.26 9.27 9.28

Thickness (m)

Permeability (m/day)

3.0 2.0 5.0

30 10 20

The transmissibility of the aquifer in m2/day is (a) 6000 (b) 18.2 (c) 20 (d) 210 The specific storage is (a) storage coefficient/aquifer depth (b) specific yield per unit area (c) specific capacity per unit depth of aquifer (d) porosity-specific detention When there is an increase in the atmospheric pressure, the water level in a well penetrating a confined aquifer (a) decreases (b) increases (c) does not undergo any change (d) decreases or increases depending on the elevation of the ground. The specific capacity of a well is the (a) volume of water that can be extracted by the force of gravity from unit volume of aquifer (b) discharge per unit drawdown at the well (c) drawdown per unit discharge of the well (d) rate of flow through a unit width and entire thickness of the aquifer In one-dimensional flow in an unconfined aquifer between two water bodies, when there is a recharge, the water table profile is (a) a parabola (b) part of an ellipse (c) a straight line (d) an arc of a circle In one-dimensional flow in a confined aquifer between two water bodies the piezometric head line is (a) a straight line (b) a part of an ellipse (c) a parabola (d) an arc of a circle For one-dimensional flow without recharge in an unconfined aquifer between two water bodies the steady water table profile is (a) a straight line (b) a parabola (c) an ellipse (d) an arc of a circle The discharge per unit drawdown at a well is known as (a) specific yield (b) specific storage (c) safe yield (d) specific capacity. The specific capacity of a well in confined aquifer under equilibrium conditions and within the working limits of drawdown (a) can be taken as constant (b) decreases as the drawdown increases (c) increases as the drawdown increases (d) increases or decreases depending upon the size of the well

Chapter

10

EROSION AND RESERVOIR SEDIMENTATION

10.1 INTRODUCTION Erosion, transportation and deposition of sediment in a watershed are natural processes which are intimately connected with the hydrologic processes. Soil and water conservation in watershed and reservoir sedimentation are important parameters affecting the success and economy of many water resources development activities in a basin. This chapter briefly deals with erosion, sediment yield and reservoir sedimentation aspects of the erosion phenomenon. This chapter is only a brief introduction to the topic. For details excellent treatises are available and Refs 2 and 5 contain some valuable source material on this topic. Erosion is the wearing away of land. Natural agents such as water, wind and gravity are eroding the land surface since geologic times. Out of many erosion causing agents the role of water in detachment, transportation and deposition is indeed very significant. Since recent past, human activities like agricultural practice, mining, building activities, railway and road construction are contributing significantly to erosion of land surface. Water storage structures like reservoirs, tanks and ponds act as receptacles for deposition of eroded material.

10.2 EROSION PROCESSES Processes Erosion takes place in the entire watershed including the channels. During a rainfall event, when rain drops impact on a soil surface, the kinetic energy of the drops breaks the soil aggregates and detaches the particles in the impact area. The detached particles are transported by surface run off. Depending upon the flow conditions, topography and geometry of the channel etc. there may be some deposition of the eroded material enroute. Erosion takes place in various modes, which can be classified as follows: Inter-Rill Erosion In this the detached particles due to raindrop impact are transported over small distances in surface flow of shallow depth without formation of elementary channels called rills. The mode of transport is essentially sheet flow and the inter-rill erosion from this mode is known as sheet erosion. Sheet erosion removes a thin covering of soil from large areas, often from the entire fields, more or less, uniformly during every rain which produces a run-off. The existence of sheet erosion is reflected in the muddy colour of the run-off from the fields.

Erosion and Reservoir Sedimentation

375

Rill Erosion Rills are elementary channels which form during the surface runoff event due to the concentration of flow. These are temporary features and facilitate channelling of overland flow. The flow in rills cuts the surface, detaches and transports the sediment in surface runoff. Gulley Erosion Gullies are formed due to confluence of many rills and formation of a major rill. When a major rill becomes deeper and steeper a gulley is formed. Gullies are capable of transporting larger amounts of sediment. The sediment removed due to formation, enlargement and deepening of gullies is known as gulley erosion. Enlarged gullies become permanent topographic features. Gullies are the most visible evidence of the destruction of soil. The gullies tend to deepen and widen with every heavy rainfall. Further, they cut up large fields into small fragments and, in course of time, make them unfit for agricultural operations. Channel Erosion Channels are permanent topographic features formed due to confluence of gullies. Channel erosion includes stream bed and bank erosion and flood plain scour. Channel erosion is significantly larger than sheet erosion.

Factors Affecting Erosion The quantity of sediment that is produced by erosion in a watershed depends upon a host of factors related to climate, soil, topography soil cover and human activities in that watershed. The major effects of these parameters are summarized in Table 10.1. Table 10.1 Factors Affecting Erosion Factor Climate Soil Characteristics

Parameter Rainfall intensity Duration of rainfall Temperature Soil Mass characteristics (Granulation, Porosity, Moisture content) Grain size and shape

Topography

Slope (Orientation, Degree and Length)

Soil Cover

Vegetation/plant cover

Land use (Human activities)

Agricultural practice, Mining, Roads, Building construction, etc. Reservoirs

Effect Splash erosion Flow erosion Weathering action Infiltration and Runoff rates and hence erosion rate. Erosion rate and transportation mode. Steeper slope: Higher energy of flow, higher erosion and transportation rates. Retardation of flow and erosion rates, Protection from splash erosion. Increased erosion rates Sedimentation

Gross Erosion, Sediment Yield and Delivery Ratio Gross erosion is the sum of all erosions in watershed. Total sediment outflow from a watershed at a reference section in a selected time interval is known as Sediment yield.

376 Engineering Hydrology Not all the sediment produced due to erosion in a watershed is transported out of it as there will be considerable temporary depositions in various phases and locations. As such, the sediment yield is always less than the gross erosion. The ratio of sediment yield to gross erosion is known as sediment delivery ratio. The sediment yield of a watershed varies with the size of the contributing area. For purposes of comparing the sediment production rate of different areas it is customary to convert the sediment yield data to the yield per unit of drainage area to obtain sediment–production rate of the catchment, which is usually expressed in units of tonnes/km2/year (or in ha-m/km2/year).

10.3 ESTIMATION OF SHEET EROSION Estimation of sheet erosion is of utmost importance in soil and water conservation practice and management of watershed. Considering different weightages to the various factors affecting the erosion process, several methods have been proposed to estimate the sheet erosion rate in a watershed. Two popular methods are described below.

Universal Soil Loss Equation (USLE) The universal soil loss equation is the most widely used tool for estimation of soil loss from agricultural watersheds for planning erosion control practices. The USLE is an erosion prediction model for estimating long term averages of soil erosion from sheet and rill erosion modes from a specified land under specified conditions. The equation is written as A = RKLSCP (10.1) where A = the soil loss per unit area in unit time. Usually the units of A are metric tonnes/ha/year. R = Rainfall erosivity factor K = Soil erodibility factor L = Slope length factor S = Slope-steepness factor C = Cover management factor P = Support practice factor (Ratio of soil loss with a support practice like contouring, strip-cropping or terracing to that with straight row farming up and down the slope). The various factors of the USLE equation are as below: Rainfall Erosivity Factor (R) The factor R is the number of rainfall erosion index units (EI30) in a given period at the study location. The rainfall erosion index unit (EI30) of a storm is defined as KE ´ I 30 EI30 = (10.2) 100 where KE = Kinetic energy of the storm. The KE in metric tones/ha-cm is expressed as KE = 210.3 + 89 log I where I = rainfall intensity in cm/h I30 = maximum 30 minutes rainfall intensity of the storm. The study period can be a week, month, season or year. The storm EI30 values for that length of period is summed up.

377

Erosion and Reservoir Sedimentation

Annual EI30 values are usually computed from data available at various meteorological stations and lines of equal EI30 lines (known as Iso-erodent lines) are drawn for the region covered by the data stations for ready use in USLE. Iso-erodent maps of Karnataka and Tamil Nadu are available in Ref. (9). In most parts of Karnataka annual EI30 values range from 250 to 500, except in Western Ghats where they range from 500 to 1500. In Tamil Nadu annual EI30 values range from 300 to 700. Soil Erodibility Factor (K) The factor K relates the rate at which different soils erode due to soil properties. These are usually determined at special experimental runoff plots or by use of empirical erodibility equations which relate several soil properties to factor K. Table 10.2 shows some computed values of K at several research stations in the country (Ref. 5). Table 10.2 Values of K at Several Stations Station

Soil

Agra Dehradun Hyderabad Kharagpur Kota Ootakamund Rehmankhera Vasad

Values of K

Loamy sand, alluvial Dhulkot silt, Loam Red chalka sandy loam Soils from lateritic rock Kota-clay loam Laterite Loam, alluvial Sandy Loam, alluvial

0.07 0.15 0.08 0.04 0.11 0.04 0.17 0.06

[Source: Ref. 5]

Topographic Factor (LS) The two factors L and S are usually combined into one factor LS called topographic factor and is given by m

where

æ l ö LS = è [65.41 sin2 q + 4.56 sin q + 0.065] 22.13 ø l = field slope length in metres m = exponent factor varying from 0.2 to 0.5 q = angle of slope

(10.3)

Crop Management Factor (C) This factor reflects the combined effect of various crop management practices. Values of factor C for regions surrounding some stations are given in Table 10.3. Table 10.3 Values of Factor C Station Agra Dehradun Hyderabad [Source: Ref. 5]

Crop Cultivated fallow Bajra Dichanhium annualtu Cultivated fallow Cymbopogon grass Strawberry Cultivated fallow Bajra

Soil Loss (Tonnes/ha per year)

Value of C

3.80 2.34 0.53 33.42 4.51 8.89 5.00 2.00

1.0 0.61 0.13 1.0 0.13 0.27 1.0 0.40

378 Engineering Hydrology Supporting Cultivation Practice (P) This factor is the ratio of soil loss with a support practice to that with straight row farming up and down the slope. Table 10.4 gives the factor P for some support practices. Table 10.4 Value of Factor P Station Dehradun

Kanpur Ootacamund

Practice

Factor P

Contour cultivation of maize Up and down cultivation Contour farming Terracing and bunding in agricultural watershed Up and down cultivation of Jowar Contour utilization of Jowar Potato up and down Potato on contour

0.74 1.00 0.68 0.03 1.00 0.39 1.00 0.51

[Source: Ref. 5]

Use of USLE USLE is an erosion prediction model and its successful application depends on the ability to predict its various factors with reasonable degree of accuracy. Based on considerably large experimental data base relating to various factors of USLE available in USA, this equation is being used extensively in that country to provide reliable estimates of erosion in a variety of situations related to in small agricultural watersheds. It should be noted that to estimate sediment yield of a watershed using USLE, information on sediment delivery ratio of the watershed would be needed. Based on 21 observed points and 64 estimated erosion values of soil loss obtained by use of USLE at points spread over different regions of the country, Gurmeet Singh et al (6) have prepared Iso-erosion rate map of India. Soil erosion rates have been classified by them into 6 categories and the area of the country under different classes of erosion are found to be as shown in Table 10.5. Table 10.5 Distribution of Various Erosion Classes in India Range (Tonnes/ha/year) 0– 5 5 – 10 10 – 20 20 – 40 40 – 80 > 80

Erosion Class

Area (km2)

Slight Moderate High Very high Severe Very severe

801,350 1,405,640 805,030 160,050 83,300 31,895

[Source: Ref. 6]

Modified Universal Soil Loss Equation (MUSLE) The USLE was modified by Williams in 1975 to MUSLE by replacing the rainfall energy factor with a runoff factor. The MUSLE is expressed as (10.4) Y = 11.8(Q ´ qp)0.56 K(LS)CP

Erosion and Reservoir Sedimentation

379

where

Y = the sediment yield from an individual storm (in metric Tonnes) Q = the storm runoff volume in m3 qp = the peak rate of runoff in m3/s and other factors K, (LS), C and P retain the same meaning as in USLE (Eq. 10.1). In this equation Q and qp are obtained by appropriate runoff models (Chapters 5 and 6). In this model Q is considered to represent detachment process and qp the sediment transport. It should be noted that MUSLE is a sediment yield model and does not need separate estimation of sediment delivery ratio. Also it is applicable to individual storms. It is believed that MUSLE increases sediment yield prediction accuracy. From modelling point of view, MUSLE has the advantage that daily, monthly and annual sediment yields of a watershed can be modelled by combining appropriate hydrologic models with MUSLE.

10.4 CHANNEL EROSION The channel erosion comprises erosion in bed, sides and also flood plain of the stream. A channel flowing in a watershed transports the runoff that is produced in the catchment and also the erosion products, out of the watershed. The total sediment load that is transported out the catchment by a stream is classified into components depending upon their origin as: 1. Wash load 2. Bed material load (i) Bed load (ii) Suspended load

Wash Load It is sediment originating from the land surface of the watershed and is transported to the stream channel by means of splash, sheet, rill and gully erosion. Wash load is generally composed of fine-grained soils of very small fall velocity.

Bed Material Load The sediment load composed of grain sizes originating in the channel bed and sides of the stream channel. Bed Load It is the relatively coarse bed material load that is moved at the bed surface through sliding, rolling, and saltation. Suspended Load The relatively finer bed material that is kept in suspension in the flow through turbulence eddies and transported in suspension mode by the flowing water is called suspended load. The suspended load particles move considerably long distances before settling on the bed and sides. In a general sense, bed load forms a small part of total load (usually < 25%) and wash load forms comparatively very small part of the total load. The mechanics of bed material transport in channels, viz. bed load and suspended load have been studied in extensive detail and treatises on the subject are available (for example Ref. 4).

Measurement While a large number of devices are available for measuring bed load for experimental/special investigations, no practical device for routine field measurement of bed

380 Engineering Hydrology load is currently in use. For planning and design purposes the bed load of a stream is usually estimated either by use of a bed load equation such as Einstein bed load equation4 or is taken as a certain percentage of the measured suspended load. Table 10.6 gives some recommended values for use in preliminary planning purposes. Table 10.6 Approximations for Bed Load Concentration of Type of material Texture of Percent of measured suspended load forming the stream suspended material suspended load that ( ppm) channel could be taken as Bed load Less than 1000

Sand

Less than 1000

Gravel, rock or consolidated clay Sand

1000 to 7500 1000 to 7500 Over 7500 Over 7500

Gravel, rock or consolidated clay Sand Gravel, rock or consolidated clay

Similar to bed material Small amount of sand Similar to bed material 25 percent sand or less Similar to bed material 25 percent sand or less

25 to 150 5 to 12 10 to 35 5 to 12 5 to 15 2 to 8

[Source: Ref. 7]

The suspended load of a stream is measured by sampling the stream flow. Specially designed samplers that do not alter the flow configuration in front of the sampler are available. The sediment from the collected sample of sediment laden water is removed by filtering and its dry weight is determined. It is usual to express suspended load as parts per million (ppm) on weight basis as

Weight of sediment in sample é ù 6 Cs = ê ú ´ 10 Weight of (sediment + water) of the sample ë û Thus the sediment transport rate in a stream of discharge Q m3/s is Qs = (Q ´ Cs ´ 60 ´ 60 ´ 24)/106 = 0.086QCs tonnes/day Routine observations of suspended load are being done at many stream gauging stations in the country. At these stations in addition to stream flow discharge Q the suspended sediment concentration and hence the suspended sediment load Qs is also noted. The relation between Qs (tones/day) and stream discharge Q (m3/s) is usually represented in a logarithmic plot (Fig. 10.1) known as sediment rating curve. The relationship between Qs and Q can be represented as Qs = KQn (10.5) where the exponent is usually around 2.0. The sediment rating curve in conjunction with the stream flow hydrograph can be used to estimate the suspended sediment load transport in the stream in a specified

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381

Fig. 10.1 Sediment rating curve (Schematic) time interval. However, it should be remembered that due to inherent inaccuracies the sediment load obtained by using sediment rating curve is less accurate than that obtained by observed flow hydrograph and sediment concentration data at the gauging station. A method of estimating the annual sediment yield of a watershed by using the sediment rating curve is described in Sec. 10.6.

10.5

MOVEMENT OF SEDIMENT FROM WATERSHEDS

As indicated earlier not all sediment produced in an erosion process in the watershed is transported out of the catchment in a real time basis. Due to loss of momentum of the converying mechanism, considerable deposition occurs mostly in areas of the catchment with low slope, high roughness or very low velocities due to large expansion of flow area. The ratio of sediment yield to the gross erosion in the watershed, called sediment delivery ratio (SDR), is an important parameter in quantitative estimation of sediment yield. The values of average annual SDR vary in a wide range as this parameter depends on a host of parameters. Out of the many parameters the significant ones are: (i) the size of the watershed, (ii) the channel density, and (iii) the relief length ratio. The size of the watershed play an important role in controlling the deposition opportunities for the eroded sediment, the larger the area larger is the opportunity for the sediment to be deposited in the catchment and hence lower SDR. The relief ratio of the watershed is a measure of the average slope of the watershed and as such higher values of relief ratio can be associated with larger transportation rates and hence larger values of SDR. Similarly the SDR is generally higher for well-defined channel network of higher density as the transportation of erosion products out of the catchment is highly facilitated by such channel networks. The variation of SDR with catchment area and relief can be expressed as (10.6) SDR = KA–m (R/L)n where A = Watershed area R = watershed relief (Elevation difference) L = Watershed length K, m and n are positive coefficients.

382 Engineering Hydrology Values of K, m and n applicable to a homogeneous region can be estimated by using observed data from experimental watersheds.

10.6 SEDIMENT YIELD FROM WATERSHEDS Estimation of sediment yield from a watershed is of utmost importance in the soil and water conservation practice in the watershed and in planning, design and operation of reservoirs. While the procedure for estimation of sediment yield is generally problem specific in view of many practical constraints relating to availability of quality data, a few commonly used procedures are described below. (1) Flow Duration Curve and Sediment Rating Curve Procedure (2) Reservoir Sedimentation Surveys (3) Estimation of Watershed Erosion and Sediment Delivery Ratio

Flow Duration Curve and Sediment Rating Curve Procedure This procedure uses the sediment rating curve of a stream to operate on the flow duration curve of the stream at the same location to obtain weighted expected daily suspended sediment transport load. This when multiplied by 365 days gives the estimated annual suspended sediment load yield at the site. The flow duration curve of the stream is developed by using available gauged daily discharge data records of sufficiently long length (Sec. 5.5, Chap. 5). The result is expressed as a graph or a table of exceedence probabilities (in percentages) of levels of daily discharge Q. The sediment rating curve of the steam at the gauging site is prepared by using gauged suspended sediment load Qs (tonnes/day) and the corresponding daily discharge Q (m3/s), as described in Sec. (10.4). The sediment rating curve is operated on the flow–duration curve as mentioned below: l The flow duration curve is considered divided into a large number of sections (say 10–20 sections). The sections need not be uniform and it is desirable to provide more sections at low exceedence probabilities. l Note the ranges of various intervals and also the mid-point value of each interval, (pi). l The discharge value QI (cumecs) corresponding to each mid-point value of exceedence, pi is noted. l Using the sediment rating curve, the value of suspended sediment load Qsi (tonnes/ day) corresponding to each Qi is calculated. l Expected daily suspended sediment discharge at each probability level pi is EQsi = piQsi. l Total weighted expected daily suspended sediment load Qsd = Spi Qsi l Expected total annual suspended sediment yield Yss = 365 ´ Qsd l The bed load (Yb) is calculated either as a percentage of annual suspended load yield (Yss) as in Table 10.4 or by using appropriate bed load equation. l Total annual sediment yield at the station Y = Yb + Yss Example 10.1 given below explains this procedure. EXAMPLE 10.1 The salient co-ordinates of the flow duration curve of a stream at a gauging station is given below:

Erosion and Reservoir Sedimentation

Exceedence Probability range (%) 0.1–1.0 1.0–5.0 5.0–10.0 10.0–15.0 15–20 20–30 30–40

Mean Daily Discharge at mid-point of the interval (Cumecs) 250 200 160 135 120 100 80

383

Exceedence Mean Daily Discharge Probability at mid-point of the range (%) interval (Cumces) 40–50 50–65 65–80 80–90 90–95 95–99.0

65 50 40 25 15 10

The gauging station is at the outlet of a watershed of area 3000 sq. km. The sediment rating curve at the station is given by the relation Qs = 0.80 Q1.84 where Qs is the suspended sediment load in tonnes/day and Q = discharge in m3/s. Estimate (i) the total sediment yield of the watershed by assuming the bed load to be 5% of the suspended load, and (ii) the annual average concentration of suspended load.

S OLUTION : Plot the flow duration curve on a logarithmic plot for using it to determine the discharge corresponding to any chosen exceedence probability through interpolation, if necessary (Fig. 10.2). Thirteen sections of the flow duration curve are selected and through appropriate interpolations their mid-values of the intervals are read from Fig. 10.2 and values entered in Table 10.7. The computations are effected in Table 10.7. In Fig. 10.2 Flow Duration Curve – Example 10.1 this Table (i) Col. 1 shows the 13 sections into which the exceedence probability is divided. (ii) Col. 2 is the interval of probability range of Col. 1. (iii) Col. 3 is the mid-point of interval of Col. 1. (iv) Col. 4 is the mean daily discharge corresponding to mid point value (Col. 3) and is obtained from flow duration curve, (Fig. 10.2). (v) Suspended sediment discharge in tonnes/day is calculated for each value of Co1. 4 by using the equation Qs = 0.80 Q1.84. (vi) Col. 6 is the Expected daily sediment load of known level of exceedence probability and is obtained as a product of Col. 2 and Col. 5 and divided by 100 to account for percentage values. (vii) Co1. 7 is the corresponding water flow in units of cumec. day: = [Col. 2 ´ Col. 4/100] The total expected mean daily suspended sediment load is 2904 tonnes, obtained as the sum of Co1. 6 values.

384 Engineering Hydrology Table 10.7 Computation of Suspended Sediment Load 1

2

Exceedence Frequency range (%)

Interval (%)

3

4

5

6

Midpoint Mean Daily Sediment (%) Discharge Discharge (Cumec) (tonnes/day)

7

Expected Volume of Sediment Water flow Load per (cumec. day) day (Tonnes) [2] ´ [5]/100 [2] ´ [4]/100

0.1–1.0 1.0 –5.0 5.0–10.0 10.0–15.0 15–20 20–30 30–40 40–50 50–65 65–80 80–90 90–95 95–99.0

0.9 4 5 5 5 10 10 10 15 15 10 5 4

0.55 3.0 7.5 12.5 17.5 25 35 45 57.5 72.5 85 92.5 97.0

250 200 160 135 120 100 80 65 50 40 25 15 10

20668 13708 9092 6651 5355 3829 2540 1733 1070 709 299 117 55 Total

186.0 548.3 454.6 332.6 267.8 382.9 254.0 173.3 160.4 106.4 29.9 5.8 2.2 2904

2.25 8.00 8.00 6.75 6.00 10.00 8.00 6.50 7.50 6.00 2.50 0.75 0.40 72.65

Over one year, suspended sediment load yield is = 365 ´ 2904 = 1,059,960 tonnes. Thus suspended load yield = 1.06 million tonnes/year. Bed load (at 5% of suspended load yield) = 0.05 ´ 1,059,960 = 52998 Tonnes Total Sediment Yield = 1,112,958 tonnes = say 1.113 million tonnes/year For a catchment area of 3000 sq.km kill, Sediment yield rate = 1,113,000/3000 = 371 tonnes/sq. km per year. (ii) Water Yield: Mean daily yield = 72.65 cumec. day Annual yield = 365 ´ 72.65 = 26517.25 cumec. days = 26517.25 ´ (60 ´ 60 ´ 24)/106 = 2291 million m3. Considering annual values Average concentration of Suspended Load =

1.113 ´ 106 ( 2291 ´ 106 ) + (1.113 ´ 106 )

´ 106

= 485.6 = say 486 parts per million (ppm) by weight.

Reservoir Sedimentation Surveys Reservoir sedimentation surveys are conducted to get reliable data relating to various aspects of sedimentation such as (i) rate of sedimentation, (ii) sediment densities, (iii) depositional pattern, and (iv) loss of storage capacity of the reservoir at various elevations. The conventional reservoir survey is a hydrologic survey using echo depth recorder along pre-established range lines on the water spread of the reservoir. Depth measurements are taken from a good quality boat with adequate safety provisions by

Erosion and Reservoir Sedimentation

385

positioning the boat at a desired point on a given range line. The basic measurements are depth of water at the location of the boat and the fixing of the position of the boat with respect to appropriate reference co-ordinates. The depth measurement is done usually by using an echo depth recorder of appropriate accuracy. The position fixing of the boat is through standard land survey techniques through use of Theodolites. Nowadays, use of Total Station units are very common as it considerably reduces the observational time and computational effort. In addition to the depth and position observations, sediment samples are taken at a number of locations in the reservoir to assess the composition and density of the sediment deposits. Use of Differential Global Positioning System (DGPS) along with an echo recorder in the boat enables faster data acquisitioning with better accuracy. Details of the DGPS methodology adopted by CWC are given in Ref. (1). The data from a reservoir survey is analyzed to produce contour map of the bed of the reservoir. Some of the end products of the analysis of reservoir survey data are l Area–Elevation–Capacity curve of the reservoir l Description of deposition pattern (Qualitative and quantitative) l L-section of the delta deposition l Sediment density at key locations l Average sediment yield from the catchment during the interval between two successive surveys. Periodic reservoir surveys are essential to efficient management of major reservoirs. Using remote sensed images of the reservoir taken at frequent intervals in monsoon and non-monsoon periods, the areal extent of the water spread at various elevations can be established very accurately. Further, using the observed reservoir levels corresponding to the date and time of the images, the area elevation capacity curve of the reservoir covering a substantial portion of the reservoir can be established by back office computations only. It may be noted that the reservoir levels are routinely observed at dam site in all reservoirs. This procedure of using remote sensed images is extremely useful in monitoring reservoir sedimentation and efficacy of catchment soil conservation practice.

Estimation of Watershed Erosion and Sediment Delivery Ratio For very small watersheds having predominantly agricultural land use, the sediment yield can be calculated by using USLE or MUSLE with appropriate factors applicable to the site. If USLE is used the sediment delivery ratio (SDR) will have to be estimated. When regional relations for SDR are not available, SDR applicable to the site will have to be established by empirical equations calibrated by using local information and observed values. The sediment yield is obtained by multiplying gross watershed erosion by SDR.

Empirical Equations Many empirical equations and procedures have been developed for estimating sediment yield at the outlet of a watershed. A few of these in common use in India or developed by use of Indian data are given below:

386 Engineering Hydrology Khosla’s equation (1953) (Ref. 8) The annual sediment yield on volume basis is related to catchment area as: Annual sediment yield rate (on volume basis) 0.00323 qsv = Mm3/km2/year (10.7a) A0.28 or Volume of sediment yield per year from the catchment is Qsv = 0.00323 A0.72 Mm3/year (10.7b) 2 where A = area of catchment in km . This equation is in common use in many parts of the country to estimate the annual sediment volume inflow into a reservoir. The observed data of Khosla had an upper average limit of 3.6 ha.m/100 sq.km and the absolute maximum limit of observed data was 4.3 ha.m/100 sq.km. While this equation has been used in many of the reservoirs in the country up to about 1970, the observed data of actual sedimentation of many reservoirs indicate that the Eq. 10.7(a) underestimates the sedimentation rate. Joglekar’s Equation (1960): (Ref. 8) Based on data from reservoirs from India and abroad, Joglekar expressed the annual sediment yield rate as

0.00597 Mm3/km2/year A0.24 or Volume of sediment yield per year from a catchment area is Mm3/year Qsv = 0.00597A0.76 In these equations A = area of catchment in km2. qsv =

(10.8a) (10.8b)

Dhruv Narayan et al’s Equation (1983): (Ref. 3) In this annual sediment rate is related to annual runoff as Qs = 5.5 + 11.1 Q (10.9) where Qs = annual sediment yield rate in tonnes/year from the watershed Q = annual runoff volume in M.ha.m Garde and Kothyari’s Procedure A detailed procedure for sediment yield estimate for Indian catchments has been developed by Garde and Kothyari3 (1987). Reference 3 contains a map of India with iso-erosion lines (in tonnes/km2/year) developed by using this procedure.

10.7 TRAP EFFICIENCY Deposition Process When a river enters a reservoir it suffers a massive enlargement of cross section of flow and consequently a large reduction of flow velocity results. The heavy sediment particles are deposited at the mouth of the reservoir in the form of a delta deposit. The sands and gravels are deposited first and the finer particles are deposited farther downstream. The sediment deposits could be classified as top set beds, foreset beds and bottomset beds. The topset beds are composed of coarse sediments of large particle size and foreset beds are of coarse sandy particles. Bottomset beds are of fine particles. Generally topset beds have flat slopes approximately at half the slope of the original channel bed. The foreset slopes are steeper and are about 5 to 7 times steeper

Erosion and Reservoir Sedimentation

387

than the topset slopes. Delta deposit forms at the mouth of the river entering the reservoir and may cause rising of the backwater profile in the channel upstream of the reservoir. Profile of a typical reservoir delta is shown in Fig. 10.3.

Fig. 10.3 Schematic Representation of Reservoir Delta Very fine particles of clays and colloids remain suspended and are transported to the remaining parts of the reservoir. The reservoir acts as a sedimentation tank and the suspended particles settle down gradually in course of time depending upon their settling velocities and reservoir operation. In the process of overflow and reservoir withdrawals, some suspended sediment passes out of the reservoir to downstream locations. Sometimes river water containing high levels of fine to very fine sediment behaves like a high density fluid and flows at the bottom of the reservoir as a gravity current with its own identity. Such flows termed density currents or turbidity currents, generally move very slowly causing a layer of high density sediment matter suspension at the reservoir bed. The bottom layers of this gradually gets compacted over a long length of time.

Trap Efficiency Out of the total quantity of sediments brought to the reservoir through the channel system of the catchment a major portion of the sediment is deposited in the reservoir and the balance is moved downstream by overflow and reservoir withdrawals. The amount of sediment trapped in the reservoir is of importance in the long term planning and operation of the reservoir. The ability of a reservoir to trap and retain incoming sediment is known as trap efficiency and is usually expressed as a percent of sediment yield of the catchment retained in the reservoir. Trap efficiency of a reservoir depends on a host of parameters the important ones being (a) sediment characteristics, (b) detention–storage time, (c) nature of outlets, and (d) reservoir operation. As such, the trap efficiency becomes reservoir specific. However, for planning purposes the correlation of trap efficiency with capacity— Inflow ratio (C/I) of the reservoir, developed by Brune2 is commonly used. Figure 10.4 shows the median and envelope curves for normal ponded reservoir relating the trap efficiency (ht) with C/I ratio. Brune developed these curves on the basis of observed data from 40 reservoirs covering C/I values ranging from 0.0016 to 2.00. Figure 10.4 shows that for the median curve ht » 100% for C/I > 0.70. For ranges smaller than 0.70, the trap efficiency can be expressed as

388 Engineering Hydrology

Fig. 10.4 Brune’s Curve of Trap Efficiency of a Reservoir (10.10) ht = K ln(C/I) + M where ht = trap efficiency in percent C/I = Capacity –inflow ratio where C = Capacity of reservoir at FRL in Mm3 and I = annual inflow into reservoir in Mm3 K and M are coefficients dependent on C/I. C/I

K

M

0.002 to 0.03 0.03 to 0.10 0.10 to 0.70

25.025 14.193 6.064

158.61 119.30 101.48

10.8 DENSITY OF SEDIMENT DEPOSITS Sediment load whether computed by equations or by direct observations are usually expressed in terms of its dry weight basis. However, to estimate the volume occupied by a given weight of sediment, it is necessary to know the unit weight of deposited sediment. The unit weight (also known as specific weight) is expressed as the ratio of dry weight of the sediment (say tonnes) in unit volume (say in m3) of the sediment deposit in the reservoir. The unit weight or sediment deposits varies over a wide range depending upon the composition, reservoir operation and consolidation undergone by the deposit over time. Typical values lie in the range of 0.3 to 2.0 tonnes/m3, with an average of around 1.3 tonnes/m3. Since sediment deposited in a reservoir gets compacted during time period through a consolidation process, the unit weight increases with time logarithmically. A commonly used formula for rough estimation of unit weight is due to Koelzer and Lara and is given by Psa Psi Pcl (W1 + B1 log T) + (W2 + B2 log T) + (W + B3 log T ) WT = 100 100 100 3 (10.11) in which WT = unit weight of deposit of age T years psa, psi and pcl = percentage of sand, silt and clay, respectively, on weight basis present in the sediment deposit.

389

Erosion and Reservoir Sedimentation

W1, W2 and W3 = unit weight (dry) of sand, silt and clay, respectively, at the end of the first year. B1, B2 and B3 = constants relating to compacting characteristics of the sediment components. T = age of sediment in years. Typical values of the parameters given by Koelzer and Lara are given in Table 10.8. Table 10.8 Values of Coefficients W and B in Eq. 10.11 Reservoir operation

Sediment always submerged or nearly submerged Normally a moderate reservoir drawdown Normally considerable reservoir drawdown Reservoir normally empty

Sand

Silt

Clay

W1 (kg/m3)

B1

W2 (kg/m3)

B2

W3 (kg/m3)

B3

1490

1040

91.3

480

256.3

1490

1185

43.3

737

171.4

1490 1490

0 0

1265 1315

16.0 0

961 1250

96.1 0

[Source: Ref. 8]

Using Eq. 10.11, the average unit weight of deposit Wav during a period of T years is obtained as éì T ö ü ù ln T ý - 1ú (10.12) Wav = WT1 + 0.4343Bw ê íçæ ÷ T 1 ø þ û ë îè where WT1 = initial unit weight in tonnes/m3 and Bw = weighted value of B in Eq. (10.11) in decimal, weightages being fraction of sand, silt and clay in the sample = (psa × B1 + psi × B2 + pcl × B3)/100 The average unit weight value Wav is used in estimating the time period required to reduce the capacity by a defined fraction due to sedimentation. The value of W1, W2 and W3 as well as B1, B2 and B3 used by different agencies differ over a wide margin. As such the values of Table 10.7 are only indicative values. Reference (7) contains valuable data pertaining to unit weights of sediments of many Indian reservoirs. In estimating the time required for a certain capacity of a reservoir to be filled up by sediment, a trial and error and step-wise procedure is adopted. Example 10.4 illustrates the method. EXAMPLE 10.2 Assuming the relative density of a sand particle as 2.6 and unit weight (dry) of a cubic metre of sediment as 980 kg, estimate the weight of 1 m3 of deposited sediment in the reservoir bed. SOLUTION: In 1 m3 of sediment Volume of solids = (1 – p) m3 where p = porosity. Volume of water = p m3 Weight of solids = 980 = (1 – p) ´ 2.60 ´ 1000 Hence p = 0.623 Weight of 1 m3 of sediment deposit = (1 – 0.623) ´ 2.60 ´ 1000 + 0.623 ´ 1000 = 980 + 623 = 1603 kg.

390 Engineering Hydrology EXAMPLE 10.3 Estimate the unit weight of a reservoir sediment in the first year of its deposition if the sediment contains 20% sand, 35% silt and 45% clay by weight. Estimate the volume occupied by 1000 tonnes of sediment in the first year and in 50th year. The reservoir can be assumed to have normally a moderate drawdown. Assume the reservoir operation is such that the sediment is always submerged. SOLUTION: The unit weight (dry) of reservoir sediment deposit is given by Eq. (10.11) as Psa Psi Pcl (W1 + B1 log T) + (W2 + B2 log T) + (W3 + B3 log T) 100 100 100 psa = 20, psi = 35 and pcl = 45

WT = Here

Referring to Table 10.7, values of coefficients B1, B2 and B3 and WI, W2 and W3 are found and introduced into Eq. (10.11) to obtain 20 35 45 WT = (1490) + (1185 + 43.3 log T) + (737 + 171.4 log T) 100 100 100 WT = 1044.4 + 92.285 log T

When T = 1 year, WT1 = 1044.4 kg/m3 When T = 50 year, WT50 = 1201.2 kg/m3

1000 = 957.5 m3 1044.4 /1000 1000 = = 832.5 m3. 1201.2 /1000

volume of 1000 tonnes of sediment in first year V1 = in 50th year V50

EXAMPLE 10.4 A reservoir has a capacity of 130 Mm3 at its full reservoir level. The average water inflow and average sediment inflow into the reservoir are estimated as 200 Mm3/year and 2.00 M tonnes/year respectively. The sediment inflow was found to have a composition of 30% sand, 30% silt and 40% clay. Estimate the time in years required for the capacity of the reservoir to be reduced to 50% of its initial capacity. Assume the sediment is always submerged. SOLUTION: Initial reservoir capacity = 130 Mm3

Final reservoir capacity = 0.5 ´ 130 = 65 Mm3 Amount of sediment deposit = 65 M tonnes First trial of average unit weight: Assume a unit weight of 1.0 t/m3. Volume of total sediment deposit = 65 Mm3 Assuming a C/I ratio > 0.70 throughout and trap efficiency ht = 100% Approximate time required to fill 50% of initial capacity = 65/2.0 = 32.5 years Assume T = 33 years to calculate Wav Second Trial: Using Table 10.7, Initial unit weight W1 = (1490 ´ 0.30) + (1040 ´ 0.30) + (480 ´ 0.40) = 951 kg/m3 = 0.951 tonnes/m3 Bw = (psa B1 + psi B2 + pcl B3) = [0 + (0.3 ´ 91.3) + (0.4 ´ 256.3)] = 129.9 kg/m3 By Eq. 10.12

{

}

é 33 ù ln 33 - 1ú = 1096 kg/m3 = 1.096 tonnes/Mm3 Wav = 951 + 0.4343 ´ (129.9) ê ë 32 û The calculation for estimating the time to fill 65 Mm3 of capacity by sediment is performed in tabular form (Table 10.9).

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391

Table 10.9 Computation of Time for filling Part Capacity by Sediment 1

2

3

4

5

6

7

Second Trial Capacity D C Capacity- Trap Average C Inflow Efficiency Trap (in Mm3)

ratio

h¢t

15 10 10 10 10 10

0.650 0.575 0.525 0.475 0.425 0.375 0.325

Time to fill D C

9

Volume of Time to Sediment fill D C

Efficiency Deposited (in years) Deposited (in years)

(C/l) 130 115 105 95 85 75 65

Volume of Sediment

8

Third Trial

98.87 98.12 97.57 96.97 96.29 95.53 94.66

h¢t

per year

98.50 97.85 97.27 96.63 95.91 95.10

1.797 1.786 1.775 1.763 1.750 1.735

8.35 5.60 5.63 5.67 5.71 5.76

1.78 1.77 1.76 1.75 1.74 1.72

8.41 5.64 5.67 5.71 5.76 5.80

Total

36.73

Total

37.00

per year

In Table 10.9: Co1. 1 gives the capacity of the reservoir. The decrease in the capacity due to sedimentation is considered in 6 steps. (Note that the steps need not be equal.) Col. 2 is the decrease in capacity between two successive steps. Col. 3 is the Capacity – Inflow ratio at the beginning of the step. Col. 3 = (Col. 1)/200 Col. 4 is the trap efficiency corresponding to C/I value of Col. 3 calculated by using Eq. (10.10). Thus Col. 4 = 6.064 ´ ln (Co1. 3) + 101.48 Col. 5 is the average trap efficiency in a step Col. 6 is the volume of sediment deposited in the reservoir per year during the event represented by the step. Co1. 6 = 2.00 ´ ((Col. 5)/100)/1.096 Col. 7 is the time in years required to fill the capacity represented by the step. Col. 7 = Col. 2/Co1. 6. The sum of the time periods represented by Col. 7 is the time required to fill the capacity by 65 Mm3. Thus the total time required to reduce the reservoir capacity by 50% is T50 = 36.73 years = say 37 years. Since the value of T50 differs from the assumed value of 33 years by more than 5% further trials to refine the value of Wav are necessary. Third trial: Take T = 37 years

{

}

é 37 ù ln 37 - 1ú = 1104 kg/m3 = 1.104 tonnes/Mm3 Wav = 951 + 0.4343 ´ (129.9) ê ë 36 û Using this value of Wav = 1.104 tonnes/Mm3 Second Trial of Table 10.8 is refined as shown in Cols. 8 and 9 of Table 10.8. The total time required for filling 50% of capacity is indicated as 37 years which is the same as assumed at the beginning of this trial. Thus T50 = 37 years is the desired period.

10.9

DISTRIBUTION OF SEDIMENT IN THE RESERVOIR

Classification of Reservoirs When a sediment laden stream enters a reservoir, the sediment is deposited not only at the head of the reservoir as delta deposit but also all along the internal surface of the

392 Engineering Hydrology reservoir. The area as well as the volume distribution of accumulated sediment at various levels is an important factor in the design of reservoirs. Further, the distribution and the rate of growth of deposits decide the location of various outlets as well as the operation strategy of the reservoir. The deposition pattern of sediment depends on a host of factors which include the slope, geometry of the reservoir, particle size distribution of sediment and the operation pattern of the reservoir. On the basis of extensive field data of reservoirs in USA, Borland and Miller classified the reservoir into four standard types as mentioned below: Classification Number IV III II I

Reservoir Type

Parameter m

Gorge Hilly region Flood plain, Foot-hill region Lake

1.0–1.5 1.5–2.5 2.5–3.5 >3.5

The parameter m is the reciprocal of the slope of best fitting line obtained by plotting reservoir elevation above bed as ordinate and reservoir capacity at that elevation as abscissa on a log-log paper [Fig. 10.5(a)]. (Note that linear scales are used to measure the slope). The typical distribution of sediment in these four types of reservoirs is shown in Fig. 10.5(b). It is seen that Type I reservoirs have considerably lower percentage of silt at lower depths when compared to Type IV reservoirs. Conversely, Type IV and III reservoirs have very low percentage of sediment at top portions when compared to Type I and II reservoirs.

Methods of Predicting Sediment Distribution Two methods, both suggested by Borland and Miller, known as (i) Empirical area reduction method and (ii) Area increment method are in common use. These are described below.

Fig. 10.5(a) Determination of Parameter m

Erosion and Reservoir Sedimentation

393

Fig. 10.5(b) Typical Distribution of Sediment in various Reservoir Types Empirical Area Reduction Method (a) Data Needed 1. Elevation – Area – Capacity relationship for the reservoir at any time Ti after the construction of the reservoir. Usually at Ti = 0, i.e. at the start of the reservoir project this data will be available. 2. Estimated volume of sediment Vs to be deposited in a period (Tf – Ti) = DT years. Usually for design purposes DT = 50 years or 100 years is selected. (b) Distribution Pattern Based on the observed reservoir sediment distribution data, Borland and Miller have expressed the distribution of sediment area at any level h above the bed as Ap = C p m1 (1 - p )n1 (10.13) Area at elevation h above the bed where Ap = a dimensionless relative area = Area at initial zero elevation p = relative depth = h/H where h = height above the reservoir bed to any given elevation in the reservoir, and H = Difference in the elevations of FRL and original bed of the reservoir = depth or reservoir at Full reservoir level (FRL). (Obviously, p has a range of 0 to 1.0.) C, m1 and n1 = coefficients dependent on the Type classification of the reservoir as given below (Ref. 7):

394 Engineering Hydrology Reservoir Type

C

m1

I II III IV

5.074 2.487 16.967 1.486

1.85 0.57 1.15 –0.25

n1 0.36 0.41 2.32 1.34

(c) Procedure A trial and error procedure is adopted. The reservoir surface can be taken to be somewhat conical in shape. When a sediment volume Vs is deposited gradually over a time DT, some part of the conical portion of the reservoir completely fills up with sediment (say up to a height of ho above the vertex) and in the remaining portion the deposition will be on the surface and the cross sectional area at any elevation will be diminished, Fig. 10.6. Let the volume of sediment filled in the conical portion to a depth of ho = Vso.

Fig. 10.6 Definition Sketch 1. The elevation ho, relative to the original bed of the reservoir, up to which the sediment completely fills up the reservoir, is assumed. The top of this filled up portion is taken as the new datum, i.e., the new zero elevation. The area Ao at this depth is determined. The value of p at this level = po = ho/H. 2. The new total depth of the reservoir = H – ho 3. Volume of sediment to be distributed = Vs – Vso 4. The type classification of the reservoir is determined 5. Values of Ap are determined for various values of p (= h o/H) by using Eq. (10.13) 6. At p = po, Ap = Apo 7. Find K = Ao/Apo 8. Using this value of K, the sediment area As at any height h above, the new datum is determined as As = ApK 9. DVs = Volume or sediment deposited between two consecutive heights h1 and h2 above the new datum is determined either as

Erosion and Reservoir Sedimentation

395

DVs = (A + A2) Dh/2

…(average end area method) or as Dh …(weighted area method). DVs = ( A1 + A2 + A1 A2 ) 3 where Dh = (h2 – h1) 10. Accumulated sediment at various elevations starting from the original bed elevation are now determined. 11. The total volume of deposited sediment up to the top of the reservoir, obtained at step No. 10, must be equal to the given value of Vs. If the value found in step 10 differs from Vs considerably, say more than 2%, then the entire procedure is repeated by assuming a new value of ho, i.e. new zero elevation. Example 10.5 given below illustrates the use of this procedure. EXAMPLE 10.5 For a reservoir the capacity – area – elevation data is given below. Estimated total accumulation of sediment in the reservoir in 50 years of its operation is 100 MCM. Original bed elevation is El. 535.00 m and the spillway crest is at 546.50 m. Determine the distribution of 100 MCM of sediment in the reservoir by the empirical area reduction method. The reservoir can be taken as of Type II. [Note: For the first trial assume the level up to which the reservoir is fully covered by sediment at the end of 50 years as 539.40 m]. Elevation (m) Original Water spread area (sq. km) Original Reservoir Capacity (MCM)

535.00

Elevation (m) Original Water spread area (sq km) Original Reservoir Capacity (MCM)

536.50

538.0

539.0

539.40

540.00

2.0

4.51

6.89

8.71

11.52

15.74

5.18

13.13

20.92

24.96

33.10

541.00

542.00

543.00

544.00

545.00

546.50

26.88

38.02

47.84

57.66

67.09

81.15

54.35

86.76

244.76

SOLUTION: Table 10.10 shows the computations.

355.97

744.76

355.97

First the given Elevation-area data is enlarged through linear interpolation to cover the elevation at an average interval of 0.50 m. The incremental area between two area elements A1 and A2 separated by a height Dh is calculated as ( A1 + A2 ) DV = ´ Dh 2 The accumulated volume starting from the original bed El. 535.00 m is calculated to get original reservoir capacity – elevation data. In Table 10.9: Col. 2 = Elevation in metres Col. 3 = Original water surface area at given elevation, sq.km Col. 4 = Height above original bed elevation = [Elevation of the item – 535.00] = h Col. 5 = Original reservoir capacity in MCM. This list contains given data as well as newly generated data Col. 6 = Relative depth p = h/H = Col. 4 /11.50 Col. 7 = Function Ap calculated by Eq. l0.13 as Ap = 2.487 p0.57 (1 – p)0.41.

2

3

4

5

6

7

8

9

10

11

12

13

Depth up to spillway crest = 11.50 m Final Trial (K2 = 9.646)

14

15

Final Values

16

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17

535.0 535.5 536.0 536.5 536.6 537.0 537.5 538.0 538.5 539.0 539.4 539.5 540.0 540.5 541.0 541.5 542.0

2.00 2.77 3.55 4.35 4.51 5.16 6.02 6.89 7.80 8.71 11.52 12.22 15.74 21.31 26.88 32.45 38.02

0.00 0.50 1.00 1.50 1.60 2.00 2.50 3.00 3.50 4.00 4.40 4.50 5.00 5.50 6.00 6.50 7.00

0.00 1.19 2.76 4.73 5.18 7.11 9.90 13.13 16.80 20.92 24.96 26.13 33.10 42.33 54.35 69.16 86.76

0 0.043 0.087 0.130 0.139 0.174 0.217 0.261 0.304 0.348 0.383 0.391 0.435 0.478 0.522 0.565 0.609

0 0.409 0.595 0.735 0.760 0.848 0.942 1.021 1.088 1.143 1.180 1.189 1.224 1.251 1.268 1.277 1.276 11.52 11.60 11.95 12.21 12.38 12.46 12.45

0.00 1.16 5.89 6.04 6.15 6.21 6.23

24.96 26.11 32.00 38.04 44.19 50.40 56.63

11.52 11.46 11.81 12.07 12.24 12.32 12.30

0.00 1.15 5.82 5.97 6.08 6.14 6.16

24.96 26.11 31.92 37.89 43.97 50.11 56.26

0.00 0.76 3.93 9.24 14.64 20.13 25.72

0.00 0.03 1.18 4.44 10.38 19.05 30.50

(Contd.)

539.4 539.5 540.0 540.5 541.0 541.5 542.0

Sl. No. Elevation Original Height Original Relative Function Sediment Incremental Accumulated Revised Revised Revised Reservoir Reservoir Available (m) Water above Reservoir Depth (p) A Area sediment Sediment Sediment Incremental Accumulated Area at Capacity at reservoir spread original Capacity (Type II) (KAP) volume Volume Area Sediment Sediment the end of the end of elevation Area bed (m) (MCM) (Sq. km) (MCM) (MCM) (KAp) Volume Volume 50 years 50 years after at (sq. km) (sq. km) (MCM) (MCM) (Sq. km) (MCM) the end of (MCM) 50 years

1

Sediment Deposition Computations by Empirical Area Reduction Method Period of Sedimentation: 50 years Total Sedimentation accumulation in the period: 100 MCM Spillway crest: 546.50 m Original River bed = 535.00 First Trial (K1 = 9.761)

Table 10.10 Empirical Area Reduction Method of Determining Sediment Deposition—Example 10.6

396 Engineering Hydrology

2

542.5 543.0 543.5 544.0 544.5 545.0 545.5 546.0 546.5

1

18 19 20 21 22 23 24 25 26

Table 10.10 (Contd.)

42.93 47.84 52.75 57.66 62.37 67.09 71.81 76.53 81.15

3

5 106.99 129.67 154.80 182.40 212.40 244.76 279.47 316.55 355.97

K2 = 9.646

K1 = 9.761

7.50 8.00 8.50 9.00 9.50 10.00 10.50 11.00 11.50

4 0.652 0.696 0.739 0.783 0.826 0.870 0.913 0.957 1.000

6 1.264 1.242 1.207 1.157 1.089 0.996 0.868 0.670 0.000

7 12.34 12.12 11.78 11.29 10.63 9.72 8.47 6.54 0.00

8 6.20 6.12 5.97 5.77 5.48 5.09 4.55 3.75 1.64

9 62.83 68.94 74.92 80.68 86.16 91.25 95.80 99.55 101.19

10 12.19 11.98 11.64 11.16 10.50 9.61 8.37 6.47 0.00

11 62.39 68.43 74.33 80.03 85.45 90.48 94.97 98.68 100.30

13 44.60 61.24 80.47 102.36 126.95 154.28 184.50 217.87 255.67

15

Capacity after 50 years = 256 (MCM)

30.74 35.86 41.11 46.50 51.87 57.48 63.44 70.06 81.15

14

542.5 543.0 543.5 544.0 544.5 545.0 545.5 546.0 546.5

16

El.539.40 m is the determined new zero elevation after 50 years

6.12 6.04 5.90 5.70 5.42 5.03 4.49 3.71 1.62

12

Erosion and Reservoir Sedimentation

397

398 Engineering Hydrology First Trial: A trial and error Procedure is adopted. For the first trial, the level up to which the reservoir is fully covered by sediment at the end of 50 years is taken as 539.40 m, as per the suggestion in the problem. This would be the new datum for the bed of the reservoir at the end of 50 years. At this level: From Col. 7, A1 = 1.180, 3, From Col. 3, Original reservoir area = Ao = 11.52 km2. Coefficient K (for the first trial) = K1 = 11.52/1.180 = 9.761 Col. 8 = Represents K Ap = 9.761 ´ Col. 7 for all elevations higher than 539.40 m. This column represents the area covered by sedimentation at a particular level and hence called Sediment area. Col. 9 = Incremental sediment volume between two successive elevation calculated as (average sediment area ´ incremental depth). Col. 10 = Accumulated sediment volume starting from 24.96 MCM at El.539.40 m. Note that the value 24.96 represents the original volume of the reservoir at the elevation 539.40 m and this volume is taken as completely filled up by sediment at the end of 50 years. The last value in Col. 10 is obtained as 101.19 MCM whereas the given sediment data indicates a deposition of 100 MCM in 50 years. This indicates a need for second trial. The calculations are very near the logical final values and since the difference is slightly more than 0.5% only minor corrections are needed. Tweaking the coefficient K does this. Thus for second trial K2 = Adjusted value of K1 on a pro-rata basis of total accumulated sediment K1 ´ 100

= 9.646. Values of this second trial (with K2 = 9.646) are 101.19 shown in Cols. 11, 12 and 13. Second Trial: Col. 11 = Revised sediment area with K2 = 9.646. Col. 12 = Revised incremental sediment volume with K2 = 9.646 Col. 13 = Revised accumulated sediment volume with K2 = 9.646 Note that this second trial improves the result considerably and the accumulated sediment volume at El. 546.50 m is 100.30 MCM. The difference between this and the given value of 100.0 MCM is negligible being less than 0.5% and thus this distribution could be taken as final values. Col. 14 = Reservoir area distribution at the end of 50 years Col. 15 = Reservoir volume distribution at the end of 50 years. Col. 16 = Available reservoir elevations at the end of 50 years. Note that the new bed level of the reservoir at the end of 50 years is 539.40 m. The distribution of the area and capacity with elevation, at the beginning and at the end of 50 years is shown in Fig. 10.7 (a and b). volume =

Area Increment Method The basic assumption of this method is that the volume of sediment deposition per unit height in the reservoir is constant. This is same as assuming that the area-elevation curve after sedimentation is parallel to the curve before sedimentation. Thus the sediment area is constant at all elevations and is equal to the sediment area at the new zero elevation, h0. The distribution of sediment is given by Vs = Ao(H – h0) + V0 (10.14) where Vs = sediment volume to be distributed in the reservoir Ao = original reservoir area at the new zero level

Erosion and Reservoir Sedimentation

399

Fig. 10.7(a) Reservoir Elevation – Area Curves—Example 10.6

Fig. 10.7(b) Reservoir Elevation – Capacity Curves—Example 10.6 ho = depth at which reservoir is completely filled up = elevation of new zero elevation with respect to old bed elevation as datum Vo = sediment volume between old zero and new zero bed level H = Difference in the elevations of FRL and original bed of the reservoir = depth of reservoir at Full reservoir level (FRL), (original value). The procedure or distributing the given total sediment volume Vs is done by a trial and error procedure as detailed below: (i) Assume ho and find corresponding Vo and Ao (ii) Check whether Vs given by Eq. (10.14) agree with the given value. If not repeat with a new value of ho

400 Engineering Hydrology (iii) Sediment area at any level is Ao. Establish water surface area at any level as (original area – Ao). (iv) Over a depth Dh. Incremental sediment volume = Ao× Dh. Hence reservoir capacity after sedimentation at any level h¢ above new zero = (Original volume – Vo – Aoh¢) Example 10.6 illustrates the procedure EXAMPLE 10.6 The reservoir of Example 10.6 is expected to have 50 MCM of sediment accumulated in first 25 years of its operation. Determine the distribution of this 25 MCM of sediment by Area Increment method. SOLUTION: Given data: Vs = 50 Mm3

H = 546.50 – 535.00 = 11.50 m First Trial: Assume that the new zero elevation is 536.50 m giving ho = 536.5 – 535.00 = 1.50 m Ao = 4.35 km2 (from given data. Col. 3 in Table 10.11) Vo = volume corresponding to El. 536.50 = 4.73 Mm3 (from Col. 6 of Table 10.11) By Eq. 10.14 Vs = Vo + Ao (H – ho) = 4.73 + 4.35(11.5 – 1.5) = 48.235 Mm3 While this value is close to the given value of Vs = 50 Mm3, a new trial to get better agreement is needed. Second Trial: For the second trial assume new zero elevation as 535.60 m. ho = 536.6 – 535.00 = 1.60 m Ao = 4.51 km2 Vo = volume corresponding to El. 536.60 = 5.18 Mm3 (From Col. 6 of Table 10.11) By Eq. (10.14) Vs = Vo + Ao(H – ho) = 5.18 + 4.51 (11.5 – 1.6) = 49.83 Mm3 This Vs value is nearly equal to the given value of 50.00 Mm3 and differs by only 0.34%. Since the difference is less than the permissible 1% value, no new trial is required. The assumed zero elevation of 536.60 is considered to represent the bed elevation at the end of 25 years satisfactorily. Using this value, the distribution of sediment at different elevations is worked out as shown in Table 10.11. In Table 10.10: Cols. 2 and 3 are given data. Col. 4 is incremental height in m Col. 5 is the incremental reservoir capacity between two elevations calculated as (average area ´ incremental height) Col. 6 is cumulative value of Co1. 5 Col. 7 is sediment area at chosen ho and is constant over the full depth of the reservoir measured above the chosen new zero elevation Col. 8 is incremental sediment volume calculated as equal to [Ao ´ (incremental height)]. Col. 9 is cumulative sediment volume. Note that the values are the same as in Col.6 up to El. 536.60. Col. 10 is estimated reservoir area at the end of 25 years. This area starts from new zero elevation of 536.60 m and is equal to (Col. 3–Col. 7). Col. 11 is estimated reservoir volume at the end of 25 years. This volume starts with a zero value at new zero elevation of 536.60 m and is equal to (Col. 6–Col. 9).

10.10 LIFE OF A RESERVOIR A reservoir is designed to serve one or more specific purposes. Sedimentation causes progressive reduction in the capacity of the reservoir and this may impact on the de-

2

535.0 535.5 536.0 536.5 536.6 537.0 537.5 538.0 538.5 539.0 539.5 540.0 540.5 541.0 541.5 542.0 542.5 543.0

1

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18

2.00 2.77 3.55 4.35 4.51 5.16 6.02 6.89 7.80 8.71 12.22 15.74 21.31 26.88 32.45 38.02 42.93 47.84

3

Sl. Elevation Water No. (m) spread Area (sq. km) 0.00 0.50 0.50 0.50 0.10 0.40 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50

4

Incremental height (m)

0.00 1.19 1.58 1.97 0.44 1.93 2.79 3.23 3.67 4.13 5.21 6.97 9.23 12.02 14.81 17.60 20.23 22.68

5 0.00 1.19 2.76 4.73 5.18 7.11 9.90 13.13 16.80 20.92 26.13 33.10 42.33 54.35 69.16 86.76 106.99 129.67

6 0 0 0 0 4.51 4.51 4.51 4.51 4.51 4.51 4.51 4.51 4.51 4.51 4.51 4.51 4.51 4.51

7 0 0 0 0 0.00 1.804 2.255 2.255 2.255 2.255 2.255 2.255 2.255 2.255 2.255 2.255 2.255 2.255

8

Incremental Reservoir Sediment Incremental volume Capacity Area Sediment (MCM) (MCM) = Ao Volume (sq. km) (MCM)

Spillway crest: 546.50 m

0 1.19 2.76 4.73 5.18 6.98 9.24 11.49 13.75 16.00 18.26 20.51 22.77 25.02 27.28 29.53 31.79 34.04

9

0 0 0 0 0 0.65 1.51 2.38 3.29 4.20 7.71 11.23 16.80 22.37 27.94 33.51 38.42 43.33

10

0.0 0.0 0.0 0.0 0.0 0.1 0.7 1.6 3.0 4.9 7.9 12.6 19.6 29.3 41.9 57.2 75.2 95.6 (Contd.)

11

Cumulative Reservoir Reservoir Sediment area at the Capacity at Volume end of 25 the end of 25 (MCM) years (sq. km) years (MCM)

Table 10.11 Area Increment Method of determining Sediment Deposition—Example 10.7

Period of Sedimentation: 25 years Total Sediment accumulation in the period : 50 MCM

Erosion and Reservoir Sedimentation

401

3

52.75 57.66 62.37 67.09 71.81 76.53 81.15

4 0.50 0.50 0.50 0.50 0.50 0.50 0.50

5 25.14 27.59 30.00 32.36 34.72 37.08 39.41

6 154.80 182.40 212.40 244.76 279.47 316.55 355.97

7 4.51 4.51 4.51 4.51 4.51 4.51 4.51

El. 536.60 m is the determined new bed elevation. Total sediment load up to El. 546.50 m at the end of 25 years = 49.83 = say 50 MCM

2

543.5 544.0 544.5 545.0 545.5 546.0 546.5

1

19 20 21 22 23 24 25

(Contd.) 8 2.255 2.255 2.255 2.255 2.255 2.255 2.255

9 36.30 38.55 40.81 43.06 45.32 47.57 49.83

10 48.24 53.15 57.86 62.58 67.30 72.02 76.64

11 118.5 143.8 171.6 201.7 234.2 269.0 306.1

402 Engineering Hydrology

Erosion and Reservoir Sedimentation

403

sired performances of the reservoir at some point in time. With this in view, various definitions of specific terms related to the general term life of a reservoir are defined. Useful Life Period through which deposited sediment does not impact on the intended purposes of the reservoir. Useful life is considered to be over when an additional reservoir is to be built (or water is to imported from another source) to meet the original intended demand. Economic Life A point of time since the commissioning of the project at which the physical depreciation due to sedimentation, in conjunction with other economic and physical factors cause the operation of the reservoir, to meet intended demands, economically inefficient. Design Life A fixed period (usually 50 years or 100 years) adopted by the designers as estimate of minimum assured useful life. The present-day practice in India is to adopt 100 years as the design life of the reservoir. The CWC practice in this connection is as follows: l Volumes of sediment estimated to be deposited in the reservoir in 50 years (V50) and in 100 years (V100) of operation are worked out. l Distribution of V100 is performed and the zero level after sedimentation is established. l Minimum drawdown level (MDDL) is fixed a little above the zero level corresponding to V100 found in second step above l Distribution of sediment V50 is performed to develop area – elevation – capacity curves. This set of curves corresponding to 50 years of sedimentation is used in working-table studies, reservoir performance simulation studies, etc.

10.11 RESERVOIR SEDIMENTATION CONTROL Sedimentation of reservoirs causes great economic loss primarily due to reduction of storage capacity of the reservoirs. Other impacts of sedimentation such as increased high flood levels due to flattening of the bed slope in the river upstream of the reservoir leading to frequent inundation and water logging in the up-reservoir areas are serious in many instances. As such, monitoring and control of sedimentation forms a prime item in the management of any major reservoir project. Considering the basic natural process of erosion and transportation inherent in the phenomenon, it is obvious that the reservoir sedimentation can never be stopped but with good effort can be retarded considerably. The basic methods available for control can be listed as: l Reduction in sediment yield from the catchment l Reduction in the rate of accumulation of sediment in the reservoir l Physical removal of already deposited sediment

Reduction in Sediment Yield Various control measures that can be adopted to reduce erosion and transportation of eroded products in the catchment are dealt under the specialized interdisciplinary practice known as Soil Conservation technology. After a thorough study of the catchment area, soil and water conservation practices best suited for each sub watershed of the catchment have to be established by the specialists in the area of soil and water

404 Engineering Hydrology conservation. In a general sense, the soil conservation practices involve components such as l Terraces, strip cropping and contour bunding to retard overland flow and hence reduction in sheet erosion l Check dams, ravine reclamation structures etc. to reduce sediment inflow into the stream l Vegetal covers, grassed waterways and afforestation to reduce runoff rates and hence to reduce erosion. In view of the interlocking and interdependency feature of various aspects of soil, water, biomass production and livelihood of people living in the watersheds an integrated approach should be adopted in watershed management. Integrated operation of soil and water conservation aspects in a watershed can be represented as in Fig. 10.8.

Fig. 10.8 Integrated Soil and Water Conservation

Reduction of Accumulation of Sediment Accumulation of the sediment that flows into the reservoir can be reduced if arrangements are made for venting out the sediment through structural arrangements in the dam and appropriate reservoir operation. Some of the measures that can be adopted towards this are: l Provision of scouring sluices at lower elevations in the dam to flush out high concentration sediments and density currents l Appropriate operation of gated overflow outlets and other sluices in the dam in such a manner to allow passage of freshets with high concentration of sediments to the downstream of the dam and to catch only relatively clear latter flows for storage in the reservoir.

Erosion and Reservoir Sedimentation

405

Physical Removal of Deposited Sediments Deposited sediments can be removed by hydraulic or mechanical means. However, for large reservoirs the disposal of removed sediment does pose environmental problems and also the entire operation may not be economically feasible. However, for many small reservoirs sediment removal, popularly known as desilting can be a feasible proposition. As typical example, desilting of irrigation tanks of south India can be cited. Several thousands of tanks in South India, particularly in Andhra Pradesh, Karnataka and Tamil Nadu are in existence since several decades and are serving as sources of minor irrigation. Many of these tanks have been successfully desilted, in recent past, and their capacity restored to their original values. Acute scarcity of water, community participation and use of tank silt as soil amendment in both irrigated command area and in the up-catchment rain-fed agricultural lands have made these ventures economically viable.

10.12 EROSION AND RESERVOIR SEDIMENTATION 10.12 PROBLEMS IN INDIA Erosion Problem The India, practically all the regions are subjected to fairly serious erosion problems due to several reasons. It is estimated that out of 305.9 M ha of reported area in the country about 145 M ha is in need of soil conservation measures. Table 10.12 gives details of soil conservation problem areas in India under different land cover/use. It is seen that major part of agricultural land suffers from erosion problem and consequent loss of productivity, nutrient and soil resource. The distribution of soil erosion problem areas (as of 1985) statewise is shown in Table 10.13(a). Table 10. 12 Soil Conservation Problem Areas in India Particulars

Forest Culturable wasteland Permanent pastures and other grazing land Land under miscellaneous tree crops and groves Fallow lands: (i) Fallow lands other than current fallows (ii) Current fallows Total for Fallow lands Net area under cultivation Other land uses, not available for agriculture, forest, etc. Grand Total

Total Area (M ha) 61.170 17.362 14.809 4.218 9.168 11.132 15 137.9 50.188 305.947*

Soil-Conservation problem area (M ha) 20 15 14 1 8 7 20.5 80 — 145

*305.947 million hectares is the reported area for land-utilisation statistics out of a geographical area of 328.809 million hectares.

406 Engineering Hydrology Table 10.13(a)

State-wise Distribution of Soil Erosion Problem Areas (as of 1985)

Sl. State No.

1. 2. 3. 4. 5. 6 7. 8. 9. 10. 11. 12. 13.

Extent of Sl. State Problem area No. due to Soil Erosion (M ha)

Andhra Pradesh Assam Bihar Gujarat Haryana Himachal Pradesh Jammu & Kashmir Kamataka Kerala Madhya Pradesh Maharashtra Manipur Meghalaya

11.502 2.217 4.260 9.946 1.591 1.914 0.883 10.989 1.757 19.610 19.181 0.374 0.837

14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26.

Extent of Problem area due to Soil Erosion (M ha)

Nagaland Orissa Punjab Rajasthan Sikkim Tamil Nadu Tripura Uttar Pradesh West Bengal Arunachal Pradesh Goa Mizoram Union Territories

0.405 4.578 1.007 19.902 0.303 3.640 0.167 7.110 1.033 2.444 0.200 0.421 0.349

(Source: Ref. 5)

For purposes of developing appropriate technologies for soil conservation, Central Soil and Water Conservation Institute has considered the erosion problem areas of the country under three categories as hilly regions, ravine regions and semi-arid, black and red soil regions. The characteristic features of these regions are as in Table 10.13(b). Table 10.13(b) Region-wise Soil Erosion Problems Region

Area

Hilly Region

Western, NorthWestern & Central Himalaya Eastern Himalayan Region

Ravine Region

Extent (M ha)

Sub-areas

31.13

J & K, UP (hill Districts) and HP

17.70

Assam. Eastern states, Sikkm and West Bengal

Western Ghats

7.74

Arid to Semi arid regions

3.67

Details Area is prone to erosion hazards due to weak geology, deforestation & hill road construction.

Shifting cultivation has caused denudation and degradation of land. Heavy runoff and massive soil erosion. Heavy rainfall in the range T.N., Kerala, 1300 to 6000 mm. Prone to Karnataka and severe erosion due to deforMaharashtra estation, faulty land use and overgrazing. Parts of UP., M.P., Faulty land use, overgrazing Bihar, Rajasthan, and loss of natural land cov(Contd.)

Erosion and Reservoir Sedimentation

407

(Contd.)

Semi-arid Black and Red Soil Region

Arid to Semi-arid tropical region.

Gujarat, Punjab, W.B., I.N. and Maharashtra Rest of the country in semiarid tropical region not covered in the above

97.00

ering are the chief causes of gully and ravine formation and soil erosion. About 500 to 2000 mm of rainfall and 80 to 90% of rainfall received in 30 to 70 hours. Sheet erosion caused by high intensity rainfall.

(Source: Ref. 5)

Reservoir Sedimentation A large number of reservoirs have been built in India since 1950. Sedimentation in the reservoirs has been found to be fairly high particularly in those reservoirs sited in arid and semi-arid tropical erodible regions. Reservoir surveys conducted during 1958 to 1986 indicated that all of the surveyed reservoirs were found to be silting at a rate faster than what was anticipated. In a majority of the reservoirs about 50% of sediment is deposited in the upper 20–30% of the depth indicating deposition in the head reaches of the reservoir. Reference 7 reports the details of surveys on a large number of reservoirs. A summary of sedimentation surveys on 19 reservoirs covering different regions of the country is given in Table 10.14. It is seen from this Table that the reservoirs are losing annually a capacity of about 0.75 of its original value. Further, the range of loss of reservoir capacity is 1.79 to 0.02% and in majority of cases the actual rate of sedimentation is many times more than the designed rates. CWC (1991) found from an analysis of capacity survey data of 49 reservoirs in India that there is wide variability in rate of sedimentation in various reservoirs. The sedimentation rate in the surveyed reservoirs was found to lie in the range of 0.15 to 27.85 ha.m/100 sq.km/year.

REFERENCES 1. Agarwal, K.K. and Idicula, K.K., Reservoir Sedimentation Surveys Using Geographical Positioning Systems, The Asian GPS Conf. New Delhi, Oct. 2000, pp 47–50. 2. Chow, V.T. (Ed), Hand Book of Applied Hydrology, Section 17, McGraw-Hill Book Co., New York, 1964, pp 17-1 to 17–67. 3. Garde, R.J. and Kothyari, D.C., Sediment Yield Eistimations, J1. of Irrigation and Power, CBIP, India, Vol. 44, No. 3, 1987. 4. Garde, R.J., and Rangaraju, K.G., Mechanics of Sediment Transportation and Alluvial Stream Problems, 2nd Ed. Wiley Eastern Ltd., New Delhi, 1977. 5. Gurmel Singh et al., Manual of Soil & Water Resources Conservation Practices, Oxford & IBH, New Delhi, 1990. 6. Gurmel Singh et al., Soil Erosion Rates in India, J1. of Soil and Water Conservation, Vol. 47, No. 1, 1992, pp. 97–99. 7. Murthy, B.N., Life of Reservoir, CBIP Tech. Report No. 19, New Delhi, March 1977. 8. Mutreja, KN., Applied Hydrology, Tata McGraw-Hill, New Delhi, 1986. 9. Ram Babu et al., Distribution of Erosion Index and Iso-Erodent Maps of Tamil Nadu and Karnataka States of India, Int. conf. on Managing Natural Resources for Sustainable Agricultural Production in the 21st Century, Vol. 2, New Delhi, 2000, pp. 23–24. 10. Central Water Commission, Govt. of India, “Compendium of Silting of Reservoirs”, New Delhi, 1991.

Sriramasagar Nizamsagar Panchet Hill Maithon Ukai Kadana Pongh Tungabhadra Bhadar Gandhi Sagar Girna

Shivaji Sagar (Koyna) Hirakud Bhakra Matatila Ramganga Ichari Dhukwan Mayurakshi

1 2 3 4 5 6 7 8 9 10 11

12 13 14 15 16 17 18 19

3171.9 841.2 1581.0 1348.8 8510.0 1543.0 8579.0 3751.2 239.2 7740.0 608.8

Godavari Manjira Damodar Barakae Tapi Mahi Beas Tungabhadra Bhadar Chambal Girna and Panzam Koyna Mahanadi Satluj Betwa Ramganga Tons Betwa Mayurakshi 2987.8 8105.0 9869.0 11.3 2449.6 11.6 106.5 607.7

Storage Capacity (Mm3)

River

891 83395 56980 20720 3134 4913 21340 1860

91751 21694 10878 6294 62224 255520 12562 28180 2435 23025 4729

Catchment Area (km2)

Source: Compendium on Silting of Reservoirs in India, CWC, 1991

Name of Reservoir

Sl. No.

1961 1957 1958 1956 1975 1972 1907 1955

1970 1930 1956 1955 1972 1977 1974 1953 1963 1960 1965

Year of Impounding

6.19 4.89 5.89 10.25 7.16 3.92 27.85 6.48 11.61 8.96 7.49 7.71 6.62 5.57 6.00 22.94 1.33 0.30 16.83

3.57 2.38 6.67 9.05 1.49 1.30 NA 4.29 7.60 3.57 0.56 6.67 2.50 4.29 1.33 4.25 NA 0.43 3.75

Designed Observed rate rate (Average for period)

Sedimentation in ha-m/100 km2/year

Table 10.14 Rate of Silting in Some Reservoirs in India

10 27 29 28 10 6 73 15

14 45 29 24 12 7 12 32 11 16 14

Period (years)

0.02 0.61 0.32 1.10 1.10 0.65 0.61 0.52

1.79 1.26 0.40 0.48 0.53 0.65 0.41 0.49 1.18 0.29 0.58

Yearly Average Loss in capacity (%)

408 Engineering Hydrology

Erosion and Reservoir Sedimentation

409

REVISION QUESTIONS 10.1 10.2 10.3 10.4 10.5

10.6 10.7 10.8 10.9 10.10 10.11 10.12 10.13 10.14 10.15

Describe different forms of land erosion by water. Describe the flow-duration and sediment rating curve procedure of estimating the sediment yield of a watershed. Explain briefly the Universal Soil Loss Equation (USLE). What is Modified Universal Soil Loss Equation (MUSLE)? What is its chief advantage over USLE? Briefly explain: (a) Erosion Index (b) Sediment Delivery Ratio (SDR) (c) Bed Load (d) Suspended Load (e) Reservoir Delta What is meant by Trap Efficiency of a reservoir? What factors influence its value? Describe a commonly used method of estimating the trap efficiency of a reservoir. Describe the procedure of conducting a Reservoir survey. List the factors affecting the density of sediment deposited in a reservoir. What is the commonly used method of estimating the average density of sediment deposited over a period of T years in a reservoir? How are reservoirs classified for purposes of estimating the deposition pattern? Explain the empirical–area–reduction method of determining the sediment distribution in a reservoir. Explain the area–increment method of determining the sediment distribution in a reservoir. Explain a procedure to estimate the time taken for a reservoir to lose x% of its initial volume. List different methods available for reservoir sediment control. Write a brief note on procedures to be adopted towards reduction of sediment yield of a catchment.

PROBLEMS 10.1 For a catchment area of 1500 km2, estimate the sediment yield in ha-m/100 sq. km/ year by using (i) Khosla’s formula and (ii) Joglekar’s formula. 10.2 If the dry unit weight of a sediment deposit in a reservoir is 850 kg/m3, estimate the (a) porosity and (b) weight of 1 m3 of sediment deposit in the reservoir. [Assume relative density of sediment particles as 2.65.] 10.3 Estimate the (dry) unit weight of a reservoir sediment deposit having 25% sand, 35% silt and 40% clay, at the end of (a) one year and (b) 25 years. [Assume that normally the reservoir undergoes considerable drawdown.] 10.4 Reservoir sediment deposition survey of a reservoir indicated the following composition of sediment in a sample: Sand = 25%, Silt = 21% and Clay = 54%. The sample can be taken as a 10 year old deposit. If the dry unit weight was 1650 kg/m3, determine the accuracy of estimate of unit weight of the sample by the use of Koezler equation. The reservoir operation is of 2nd kind viz, normally moderate drawdown is expected in its operation. 10.5 A reservoir sediment is estimated through use of Koezler equation to have average unit weight of 1100 kg/m3 at the end of 35 years and 1120 kg/m3 at the end of 50 years. Estimate the average unit weight at the end of first year of deposit and at the end of 100 years. 10.6 In a reservoir the average weight of deposited sediment was found to be (i) 500 kg/m3 over a period of first ten years, and (ii) 600 kg/m3 over a period of first twenty years. Estimate the average unit weight over a period of first 50 years of the reservoir’s life.

410 Engineering Hydrology 10.7

10.8

A reservoir with a capacity of 50 Mm3 is proposed at a location in a river having the following properties: Catchment area = 200 km2 Average Annual water yield at the site = 35 cm Average Annual Sediment yield at the site = 150,000 Mm3 Estimate the time required for the loss of 30% of initial capacity of the reservoir due to sedimentation. [Assume three equal steps of capacity loss.] The reservoir is expected to be a normal ponded reservoir. A reservoir has an initial capacity of 90000 ha-m and the annual sediment load in the stream is estimated as 600 ha-m. If the average annual inflow into the reservoir is 400000 ha-m, estimate the time in years for the reservoir to lose 50% of initial capacity. In the relevant range the trap efficiency ht can be assumed to be given by ht = 6.064 Ln(C/I) = 101.48

Use five steps. 10.9 A proposed reservoir has a catchment of 2660 km2. It has a capacity of 360 Mm3 and the annual yield of the catchment is estimated as 40 cm. Assuming the average composition of sediment as 20% sand, 35% silt and 45% clay, estimate the probable life of the reservoir to a point where 40% of the reservoir capacity is lost by sedimentation. The sediment yield is estimated independently as 360 tonnes/km2/year. [Assume the reservoir to have normally a moderate reservoir drawdown. Take five capacity steps for the life calculation.] 10.10 Coordinates of suspended load rating curve and flow duration curve of a river at a gauging site is given below. Plot the respective curves and using them estimate the (a) total sediment yield at the gauging station and (b) concentration of suspended load in ppm. [Assume bed load as 10% of suspended load.] Flow Duration Curve Percent times flow equalled or exceeded 0.5–1.0 1.5–5.0 5.0–15.0 15.0–35.0 35.0–55.0 55.0–75.0 75.0–95.0 95.0–99.5

Suspended Sediment Rating Curve

Average daily discharge

Water discharge (m3/s)

Suspended load (tonnes/day)

2550 1275 735 450 200 110 50 20

2550 1250 750 450 350 225 125 85 50 25

355,000 200,000 62,500 22,500 17,500 10,000 4000 2000 500 50

10.11 A reservoir has a capacity of 180 Mm3 at its full reservoir level. The average water inflow and average sediment inflow into the reservoir are estimated as 400 Mm3/year and 3.00 M tonnes/year respectively. The sediment inflow was found to have a composition of 20% sand, 30% silt and 50% clay. Estimate the time in years required for the capacity of the reservoir to be reduced to 35% of its initial capacity. [Assume the sediment is always submerged.] 10.12 The area of a reservoir at different elevations as obtained by survey is shown in the following table. Estimate the capacity of the reservoir by using the weighted area method. Plot the capacity – elevation above bed curve on log-log axes and estimate the value of parameter m and the reservoir type.

Erosion and Reservoir Sedimentation Elevation (m)

Area (ha)

560.52 562.35 563.27 563.88 564.18 564.49 565.10 565.55 566.93 568.45 569.97

0 19.42 47.75 62.32 79.72 96.72 137.59 191.41 366.64 513.95 679.06

411

Capacity in (ha.m) 0 11.8 41.8 75.3 96.5 123.8 194.8 268.7 647.2 1313.3 2217.1

10.13 Original Reservoir the capacity – area – elevation data of Bhakra reservoir, India, is given below. Estimated total accumulation of sediment in the reservoir in 25 years of its operation is 92250 ha-m. Original bed elevation is E1.350.52 m and the spillway crest is at 512.06 m. Determine the distribution of 92,250 ha-m of sediment in the reservoir by the empirical area reduction method. The reservoir can be taken as of Type II. Assume the level up to which the reservoir is fully covered by sediment at the end of 25 years as 365.76 m. [Use average end area method for computing incremental volume.] Elevation (m)

Original area (ha)

Original capacity

Elevation (m)

Original area (ha)

Original capacity (ha.m)

350.52 365.76 381.00 396.24 400.00 411.48

0 364 1295 2428 2752 3561

0 2460 13530 43050 55350 87330

426.72 441.96 457.20 472.44 487.68 502.92 512.06

4452 5382 6799 8620 11048 13760 15378

148830 222630 317340 436650 587940 772440 910200

10.14 For a reservoir the original area – elevation – capacity relation is as given below. Over a period of 10 years, this reservoir expects a total sediment inflow of 10,000 ha-m. Determine the distribution of 10,000 ha-.m of sediment in this reservoir by the areaincrement method. [An accuracy of >99.5% in gross sediment volume is expected.] Elevation (m)

Original area (ha)

97.53 100.58 103.63 105.76 106.68 109.73

0 43.7 168.4 411.2 464.2 720.7

Original capacity (ha.m) 0 98 471 1177 1509 3321

Elevation (m)

Original area (ha)

Original capacity (ha.m)

112.77 115.82 118.88 121.92 124.97

1659 2241 3083 4346 6206

7258 13242 21300 32550 42710

412 Engineering Hydrology

OBJECTIVE QUESTIONS 10.1 In a reservoir the capacity is 20 cm and the annual inflow is estimated to be 25 cm. The trap efficiency of this reservoir under normal operating conditions is about (a) 10% (b) 45% (c) 75% (d) 100% 10.2 In a reservoir the sediment deposit is found to be made up of only sand and this deposit is always found to be submerged. The unit weight of this sediment deposit at any time T years after the commencement of operation of the reservoir is about (a) 1500 kg/m3 (b) 1500 + B Ln T kg/m3 where B is a positive non-zero coefficient (c) 750 kg/m3 (d) 750 + B Ln T kg/m3 where B is a positive non-zero coefficient 10.3 Borland & Miller’s classification of reservoirs for distribution of sediments in the reservoir is based on a parameter m. The reservoir is classified as (a) Type I if m is in the range 2.5 to 3.5 (b) Type II if m is in the range 1.0 to 1.5 (c) Type III if m is in the range 1.5 to 2.5 (d) Type IV if m is greater than 3.5 10.4 A reservoir had an original capacity of 720 ha-m. The drainage area of the reservoir is 100 sq.km and has a sediment delivery rate of 0.10 ha-m/sq.km. If the reservoir has a trap efficiency of 80% the annual percentage loss of original capacity is (a) 1.39% (b) 1.11% (c) 1.74% (d) 0.28% 10.5 The sediment delivery ratio (SDR) of a watershed is related to watershed area (A), relief (R) and watershed length (L) as (a) SDR = KAm (R/L)n (b) SDR = KA–m (R/L)–n –m n (c) SDR = KA (R/L) (d) SDR = KAm (R/L)–n where K, m and n are positive coefficients. 10.6 If erosion in a watershed is estimated as 30 tonnes/ha/year, his watershed is in erosion class designated as (a) severe (b) very high (c) high (d) moderate 10.7 The suspended sediment concentration Cs in ppm is determined from a sample of suspended sediment mixture as (a) Cs = (b) Cs = (c) Cs = (d) Cs =

[Weight of sediment in sample] [Weight of water in sample]

´ 106

[Weight of sediment in sample] [Weight of (sediment + water) in sample] [Volume of sediment in sample] [Volume of (sediment + water) in sample] [Weight of (sediment + water) in sample] [Volume of (sediment + water) in sample]

´ 106 ´ 106 ´ 106

10.8 The current CWC practice in design of reservoirs adopts minimum drawdown level (MDDL) based on the bed elevation that will be reached in the reservoir after N years of sedimentation, where N is equal to (a) 25 years (b) 50 years (c) 100 years (d) 500 years 10.9 The present CWC practice in design of reservoirs adopts area – capacity – elevation curves expected after M years of sedimentation for working table studies and checking for the performance of the project. In this M is equal to (a) 25 years (b) 50 years (c) 100 years (d) 500 years

Appendix

A

ADDITIONAL REFERENCES, SOME USEFUL WEBSITES, ABBREVIATIONS

A.1 ADDITIONAL REFERENCES 1. Bedient, P.B. and Huber, W.C., Hydrology and flood plain analysis, AddisonWesley Pub. Co., 1988. 2. Bras, R.L., Hydrology—An Introduction to Hydrologic Science, Addison-Wesley Pub. Co., 1990. 3. Chow, V.T., Maidment, D.R. and Mays, L.W., Applied Hydrology, McGrawHill Book Co., Singapore 1988. 4. Gurmeet Singh et al., Manual of Soil and Water Conservation Practices, Oxford & IBH Pub. Co., New Delhi, 1990. 5. Karanth, K.R., Hydrogeology, Tata McGraw-Hill Pub. Co., New Delhi, India, 1989. 6. Karanth, K.R., Ground Water Assessment, Development and Management, Tata McGraw-Hill Pub. Co., New Delhi, India, 1992. 7. Mutreja, K.N., Applied Hydrology, Tata McGraw-Hill Pub. Co., New Delhi, India, 1986. 8. Shaw, E.M., Hydrology in Practice, Van Nostrand (International), 1988. 9. Singh, V.P., Elementary Hydrology, Prentice-Hall, 1992. 10. Viessman, W. et al., Introduction to Hydrology, 3rd ed., Harper & Row, New York, 1989.

A.2 SOME USEUL WEBSITES RELATED TO HYDROLOGY (AS OF 2007) 1. U.S. Geological Survey www.usgs.gov 2. Hydrology Web http://hydrologyweb.pnl.gov 3. Kumar Link to Hydrology Resources www.angelfire.com/nh/cpkumar/hydrology.html 4. WRCS Hydraulic & Hydrology Software shop http://www.waterengr.com 5. New Mexico University – Earth & Environmental Science – Useful Links http://www.ees.nmt.edu

414 Engineering Hydrology 6. Yahoo Search http://dir.yahoo.com/Science/Engineering/Civil_Engineering 7. Internet Resources for Water http://www.library.ucsb.edu/istl/97-summer/internet1.html 8. Links to Interesting Water Resource web pages http://www.uswaternews.com 9. Water Meta Pages http://www.interleaves.org/~rteeter/watermeta.html 10. Directory of Hydrology related WWW sites http://hydrology.agu.org/news/resources.html

A.3 ABBREVIATIONS AET AI AMC CBIP CGWB CN CWC DAD DGPS DRH DVC El30 ER ERH FAO FEM FRL GOI GPS IMD IUH MAI MCM MDDL MOC MSL MUSLE NBSS&LUP NCIWRD NRSA PET

Actual Evapotranspiration Aridity index Antecedent moisture condition Central Board of Irrigation & Power (India) Central Groundwater Board (India) Curve number Central Water Commission (India) Maximum Depth – Area – Duration Differential Global Positioning System Direct runoff hydrograph Damodar Valley Corporation Rainfall Erosion Index Unit Effective (or Excess) rainfall Effective (or Excess) rainfall hyetograph Food & Agriculture Organisation of United Nations Organisation. Finite Element Method Full Reservoir Level Government of India Geographical Positioning System India Meteorological Department Instantaneous Unit Hydrograph Moisture availability index Million Cubic Metre Minimum Drawdown Level Method of Characteristics Mean Sea Level Modified Universal Soil Loss Equation National Bureau of Soil Survey & Land Use Planning National Commission for Integrated Water Resources Development (1999) National Remote Sensing Agency Potential evapotranspiration

Appendices

PI PMF PMP RBA RTWH SCS SDR SPF SPS SRK SWM TMC UH UNESCO USLE WMO

415

Palmer Index Probable maximum flood Probable maximum precipitation Rashtriya Barh Ayog (National Flood Commission) Roof Top Water Harvesting U.S. Soil Conservation Service Sediment Delivery Ratio Standard Project Flood Standard Project Storm Standard Runga-Kutta Method Stanford Watershed Model Thousand Million Cubic Feet Unit hydrograph United Nations Economic, Social & Cultural Organisation Universal Soil Loss Equation World Meteorological Organisation

Appendix

B

CONVERSION FACTORS

B.1 VOLUME 1 m3 = 35.31 cubic feet = 264 US gallons = 220 Imp. gallons = 1.31 cubic yards = 8.11 ´ 10–4 acre feet = 1000 litres

B.2 FLOW RATE (DISCHARGE) Unit 1 cft/s (cusec) 1 Imp. gpm 1 US gpm 1 Imp. mgd 1 acre ft/day

Cubic metres per second (m3/s)

Litres per minute (lpm)

0.02832 7.577 ´ 10–5 6.309 ´ 10–5 0.05262 0.01428

1699 4.546 3.785 3157 856.6

Litres per second (lps) 28.32 0.07577 0.06309 52.62 14.28

B.3 PERMEABILITY 1. Specific permeability, K0 1 darcy = 9.87 ´ 10–13 m2 = 9.87 ´ 10–9 cm2 2. Coefficient of permeability, K 1 lpd/m2 = 1.1574 ´ 10–6 cm/s 1 m/day = 1.1574 ´ 10–3 cm/s = 20.44 Imp. gpd/ft2 = 24.53 US gpd/ft2 = 0.017 US gpm/ft2

B.4 TRANSMISSIBILITY 1 m2/day = 67.05 Imp. gpd/ft = 80.52 US gpd/ft = 0.056 US gpm/ft

EQUIVALENTS OF SOME COMMONLY USED UNITS 1 Metre = 3.28 feet 1 Kilometre = 0.6215 mile 1 Hectare = 2.47 acres 1 sq. km = 100 ha 1 Million ü ü 810.71 Acre Cubic metre ý = ý ft. = 0.0353 (MCM) þ þ TMC

1 Foot 1 Mile 1 Acre 1 Sq. Mile 1 TMC = one thousand million cubic feet 1 Million acre feet 1 cusec. day 1 million gallons (imperial)

= = = =

ü ý= þ = = ü ý = þ

30.48 cm = 0.3048 m 1.609 km 0.405 ha 259 ha = 640 acres ü 28.317 million cubic metres ý þ (MCM)

1233.48 million cubic feet 86400 cft = 2446.9 m3 ü 160544 Cubic feet = 4546.09 ý þ Cubic metres

Answers

ANSWERS TO OBJECTIVE QUESTIONS

Chapter

1.00

1

2

3

4

5

6

7

8

9

c

d

a

b

c

d

c

a

c

2.00 2.10 2.20

c b

d d a

b a a

c d b

d c c

c b a

a b b

b d

b b

c b

3.00 3.10

c

c b

b b

d b

c c

c d

d b

b d

d c

c

4.00 4.10

b

d a

d c

b b

d a

c b

b c

a b

c c

d c

5.00 5.10

d

a c

a b

b a

a b

c c

c b

b c

c a

b

6.00 6.10 6.20

c b

c b a

a d b

b c c

a a b

c d

b a

b d

b b

b d

7.00 7.10 7.20

a d

a c

d c

a c

c a

c c

b a

b c

d c

a b

8.00 8.10 8.20

d d

a b a

b a

a b

d a

c b

b b

d c

d d

c c

9.00 9.10 9.20

b d

d c a

b c a

b b b

c d b

c d a

d d b

b a d

c c b

a a

d

a

c

b

c

b

b

c

b

10.00

Answers

ANSWERS TO PROBLEMS

+D=FJAH Q = 57.87 m3/s (i) 0.61 (ii) Increase in abstraction = 18.492 Mm3 3 Q = 6.191 m /s 1.4 S2 = 19.388 ha.m P = 1105 mm, E = 532.4 mm, ra = 0.485, rb = 0.472, rc = 0.522, rd = 0.538, rtotal = 0.518 1.6 (i) Tr = 8.2 days (ii) Tr = 4800 years (iii) Tr = 28,500 years

1.1 1.2 1.3 1.5

+D=FJAH 2.1 2.3

2.4

2.5 2.7 2.9 2.10 2.11

5 (a) 1955

2.2 12.86 cm (b) Correction ratio = 0.805, mean PA = 143.9 cm

Time since start of the storm (minutes) Intensity of rainfall in the interval (cm/h) Cumulative rainfall since start (cm)

30

60

90

120

150

180

210

3.50

4.50

12.0

9.0

5.0

3.0

1.5

1.75

4.00 10.00 14.50 17.00 18.50 19.25

Average intensity = 5.5 cm/h 36.06 mm 2.6 Years 1964, 1971, 1972, 1976 and 1980 were drought years. 7.41 cm 2.8 135 cm (a) 10.6 cm (b) 10.80 cm (c) 11.07 cm 112.03 cm (i) Average depth = 20.1 mm (ii) Depth at storm centre = 22.0 mm.

2.12 (a) (b)

Time (min) Intensity (mm/h)

10 20 114 132

30 42

40 50 60 70 120 138 198 168

80 48

90 36

Duration (min) 10 20 30 40 50 60 70 80 90 Max. Intensity (mm/h) 198 183 168 156 134.4 133 130.3 120 110.7

2.13 Duration (min)

10 Max. Depth (mm) 16

20 25

30 31

40 40

50 47

60 55

70 60

80 64

90 67

Answers

"'

2.14 Maximum Intensity

75.0 62.1 49.8 40.5 37.0 33.0 30.1 27.2 24.7 Duration in Min 10 20 30 40 50 60 70 80 90 Maximum Depth (mm) 12.5 20.7 24.9 27.0 30.9 33.0 35.1 36.2 37.0

2.15 2.16 2.18 2.19 2.20

(a) 132.50 cm (a) 118.0 cm (a) 0.167 (a) 0.605 10 years 2.21

(b) (b) (b) (b) (a)

143.0 cm T = 3.5 years 0.0153 0.01 0.155

(c) p66.7 = 88.0 cm; p75 = 84.5 cm (c) 0.183 (b) 0.00179

(c) 0.0845

+D=FJAH! 3.1 3.4 3.6 3.9 3.10 3.11 3.12

3.13 3.14

3.15 3.16 3.17 3.18 3.20

10.7 mm/day 3.2 24.5 mm 3.3 Decrease, 48 Mm3 175 mm/month 3.5 (a) 27.1 cm (b) 32.28 cm 23.4 cm 3.7 46.8 cm 3.8 11.25 cm/month 3.9 mm/day for Day 2 and Day 7; 3.6 mm/day on Day 9 fp = 1.0 + 10.45e–3.1t Kh = 4.1235 h–1, fc = 3.21 cm/h, fo = 41.278 cm/h Kostiakov: Fp = 6.733t0.7393 1 ö Green – Ampt: fp = 9.0239 æ + 3.8375 çè Fp ÷ø Philip: fp = 2.9735t–0.5 + 2.0461 Kh = 3.06 h–1, fc = 1.50 cm/h, fo = 27.935 cm/h Kostiakov: Fp = 4.245 t0.7841 Philip: fp = 1.911 t–0.5 + 1.485 1 ö Green – Ampt: fp = 3.9785 æ + 2.305 çè Fp ÷ø (a) (i) fp = 0.7598 t–1.185 (ii) Fp = 7.4827 ln t + 34.781 (b) Kh = 1.91 h–1, fc = 0.10 cm/h, fo = 10.244 cm/h fav = 1.02 cm/h (i) At t = 2.0 h fp = 1.7 cm/h (ii) At t = 3.0 h fp = 1.51 cm/h j-index = 0.42 cm/h 3.19 j-index = 0.657 cm/h, te = 3.5 hours W-index = 2.52 mm/h 3.21 R = 2.50 cm 3.22 R = 2.24 cm

+D=FJAH" 4.1

6.426 m3/s

v v v 1 (ii) (a) = 1.001 (b) = 1.00036 = v0.6 v0.6 v0.6 (0.4) m ( m + 1) 4.3 11.895 m3/s 4.4 3458.9 m3/s 4.5 103 m3/s 4.6 500 m3/s 3 3 4.7 142.8 m /s 4.8 11 km 4.9 44.25 m /s 4.10 30.18 m3/s 1.371 3 4.11 (1) Q = 159.44 (G – a) , (2) 0.968 (3) 2525 m /s, 5368 m3/s 3 4.13 a = 18.60 m 4.12 426.9 m /s 4.14 (G – 20.5) = 0.1641 Q0.4648, Stage = 26.842 m 4.15 164.4 m3/s 4.2

(i)

" Engineering Hydrology

+D=FJAH# 5.1 5.2 5.4

5.6

(a) 121 cm (b) 62.7% R = 0.4828 P – 0.2535; 5.06 Mm3 5.3 R = 0.6163 P – 21.513; 40.12 cm 10143 Mm3; 12842 Mm3 5.5 0.144 Month 3

Monthly Yield (m )

July

August

September

October

41580

430290

177120

751410

Total seasonal yield (Mm3)

5.7 5.8 5.9 5.12 5.14 5.16 5.18 5.21

1.44

(a) 59550 m3 (b) 180800 m3 CNI = 51.4, CNII = 70.7, CNIII = 85.0 5.10 620500 m3 5.11 90984 m3 346080 m3 140.15 mm 5.13 (a) 122.4 mm, (b) 105.2 mm; 16% Q75 = 14 m3/s 5.15 9545 cumec.day 5.17 365 Mm3 (a) 5700 cumec.day; (b) 82 m3/s 3 389.12 Mm 5.19 91.032 ha.m 5.20 389.12 Mm3 3 3 16.74 Mm ; 1.41 Mm /day; Nil 5.22 27 Mm3 less water

+D=FJAH$ 6.1 6.2

Krh = 0.886, Krs = 0.2217, St7 = 9.12 cumec.day (a) Krb = 0.966 (b) Q3 = 28.28 m3/s Time (h) Average ER (min)

6.5 6.6

6.7

6.8

6.4 2.47 Mm3

1

2

3

4

1.44

25.50

3.94

(Given ordinates/4.32) Base = 66 hour; qp = 15.91 m3/s at 10 hours from start Time (h)

6-h UH ord. (m3/s)

6

12

18

24

30

36

42

48

54

60 66 72

5.0 35.0 64.0 72.0 62.0 45.8 32.8 20.8 11.6 5.6 1.6

ER = 5.76 cm Time (days)

1

2

3

4

5

1-day Dist. graph (%) 0 10.50 31.50 26.25 15.50 9.25

6

7

8

5.25

2.00

6.10 70 m3/s

6.9 Ordinates of 8-h UH = (Given ordinates/4.5) 6.11 Volume of Direct Surface runoff = 5.78 Mm3 Peak runoff rate = 1376 m3/s

6.12 Time (h) Q(m3/s)

0 30

3 300

6 480

9 1410

12 2060

18 4450

24 6010

30 6010

Time (h) Q(m3/s)

36 5080

42 3996

48 2866

54 1866

60 1060

66 500

72 170

78 30

6.13 Time (h) Q(m3/s)

0 10

6 30

12 90

18 220

24 280

Time (h) Q(m3/s)

48 92

54 62

60 40

66 20

72 10

12-h UH ord. (m3/s)

0 0

6 10

12 40

18 105

24 135

Time (h) 12-h UH ord. (m3/s)

48 41

54 26

60 15

66 5

72 0

6.14 Time (h)

6.15 Time (h)

30 220

"

36 166

42 126

30 105

36 78

12 755 140

14 825 90

S-curve ord. (m3/s) 4-h UH ord. (m3/s)

0 0 0

2 25 12.5

4 125 62.5

6 285 130

8 475 175

10 645 180

Time (h) S-curve ord. (m3/s) 4-h UH ord. (m3/s)

16 855 50

18 875 25

20 881 13

22 881 3

24 881 0

26 881 0

6.16 160 m3/s

Answers

42 58

6.17 Area = 7.92 km2

Time (h) 3

S-curve ord. (m /s) 2-h UH ord. (m3/s)

6.18 Time (h)

1

2

3

4

5

6

7

0 0

5 2.5

13 6.5

18 6.5

21 4.0

22 2.0

22 0.5

22 0

6 20

12 54

18 98

24 124

30 148

36 152

42 154

48 54 138 122

Time (h) 60 6-h UH ord. (m3/s) 106

66 92

72 76

78 66

84 50

90 42

96 28

102 22

108 114 12 10

Time (h) 120 6-h UH ord. (m3/s) 6

126 3

132 1

138 0

6-h UH ord. (m3/s)

6.19 Time (h)

0 0

9-h UH ord. (m3/s)

0 0

3 4

6 9 12 15 18 21 24 27 30 29 73 129 174 191 183 158 135 115

Time (h) 9-h UH ord. (m3/s)

36 39 42 45 48 51 54 57 60 63 66 83 69 54 43 33 25 18 12 6 2 0

6.20 Time (h) Q (m3/s)

0 20

6 80

12 200

18 550

24 620

30 890

Time (h) Q (m3/s)

48 380

54 280

60 178

66 100

72 60

78 20

36 698

33 99

42 530

6.21 A = 1296 km2 Time (h) Q (m3/s)

0 25

6 75

12 225

18 375

24 525

30 600

Time (h) Q (m3/s)

48 375

54 300

60 225

66 150

72 75

78 25

36 525

42 450

"

Engineering Hydrology

6.22 80.5 m3/s 6.23 Time (h) DRH ord. (m3/s)

0 0

2 4.3

6 10 14 18 22 19.4 44.4 39.6 28.1 14.1

26 4.9

30 1.4

34 0

6.24 Time (Units of 6 h)

1 2 3 4 5 6 7 Dist. Graph ord. (%) 6.25 18.75 22.92 18.75 14.58 10.42 6.25

8 2.08

6.25 91.4% and 59.44%

6.26

Time (h) 3

3-h UH ord. (m /s)

3

6

9

12

15

18

21

24

27

60

120

90

50

30

20

10

5

6.27 tR = 6.0 h; t¢p = 27.75 h; Qp = 126 m3/s; W50 = 79 h; W75 = 45 h; Tb = 156 h 6.28 t¢p = 9 h; Qp = 86.5 m3/s; W50 = 30.7 h, W75 = 17.5 h; Tb = 52 h 6.29 Qp = 126 m3/s, Tp = 30.75 h and to be used with Table 6.12 in the Text.

6.30

6.31

Time (h)

Ordinate of 4-h UH (cm/h) Ordinate of S4-curve (cm/h) Ordinate of 3-h UH (cm/h)

0 0 0

Time (h)

1

2

3

1 2 3 1 2 3 1.33 2.67 4.0 1

2

3

4

5

6

4 3 2 4 4 4 4.0 2.67 1.33 4

5

6

7

8

1 4 0

0 4

7

8

Ordinate of S2-curve (cm/h) 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 Ordinate of 4-h UH (cm/h) 0.25 0.25 0.25 0.25

6.32

Time (h) 3

Ordinate of DRH (m /s)

1

2

3

4

5

>5

300

300

300

300

300

300

6.33 Qp = 20.48 m3/s, Tp = 1.025 h, Tb = 2.75 h DRH: A triangle with peak of 81.92 m3/s occurring at 1.025 h from start. Base = 2.75 h

6.34

Time (h)

Ord. of 2-h UH (m3/s)

Time (h)

Ord. of 2-h UH (m3/s)

0 2 4 6 16 18 20 22 24 26

0.00 2.50 7.50 12.50 15.00 13.57 12.14 10.71 69.29 37.86

8 10 12 14 28 30 32 34 36 38

17.50 19.29 17.8 16.4 6.43 5.00 3.57 2.14 0.71 0.00

Answers

" !

6.35 Area = 257.8 km2 Time (h)

Ord. of 3-h UH (m3/s)

Time (h)

Ord. of 3-h UH (m3/s)

0 1 2 3 4 5 6 7 8 9 10 11

0.0 1.8 9.8 26.0 46.0 62.3 70.7 71.8 68.5 62.8 56.0 49.0

12 13 14 15 16 17 18 19 20 21 22 23

42.3 36.0 30.0 24.3 19.0 14.5 10.8 7.5 4.5 2.0 0.5 0.0

+D=FJAH% 7.1 4.0 m3/s 7.2 10.0 m3/s 7.3 19.65 m3/s 7.4 Qp = 55.08 m3/s 3 7.5 qm = 311.88 m /s occurs at the end of 5 hours after the commencement of the storm 7.7 Qp = 6.42 m3/s 7.6 Qp = 2.08 m3/s 7.8 See Fig. AnsP–7.8 7.9 Qp = 0.345 m3/s

Fig. AnsP–7.8 Answers to Problem 7.8

" " Engineering Hydrology 7.10 (a) 0.025 7.11 (a) 0.41 (d) 0.000833

7.12

7.13

(b) 0.397 (b) 0.358 (e) 0.636

N K(T, N)

35 5.6421

(c) 0.975 (c) 0.02

45 5.5221

QT m3/s for T = Gumbel Log Pearson-III Log Normal

55 5.4420

50 5763 5296 5334

100 6392 5823 5880

7.14 100 years

7.15 85 years

7.17 QT m3/s for T =

50 794 696

Log Pearson-III Log Normal

60 5.4100

65 5.3832

1000 8471 7588 7730

7.16 100 years 100 928 771

200 1077 846

1000 1496 1025

7.18 22950 m3/s 7.19 (i) 7896 m3/s, (ii) 8103 m3/s 7.20 Ganga: Q100 = 16359 ± 2554 m3/s Q1000 = 22023 ± 3744 m3/s 3 Yamuna: Q100 = 17298 ± 3885 m /s Q1000 = 23935 ± 5721 m3/s 7.21 567 m3/s 7.22 (a) x = 385 m3/s; sn – 1 = 223 m3/s (b) 1525 m3/s 7.23 Time (h) Q (m3/s)

0 50

12 104

24 482

36 1669

48 3139

60 3699

72 3358

Time (h) Q (m3/s)

96 1928

108 1268

120 753

132 393

144 183

156 51

168 50

0 0

6 2.0

12 4.4

84 2603

7.24 Design Storm Time (h) Design strom rainfall excess (cm)

18 6.4

24 2.4

Flood Hydrograph Time (h) Q (m3/s)

0 20.0

6 45.0

12 125

18 285

24 475

30 620

36 666

Time (h) Q (m3/s)

42 568

48 416

54 264

60 132

66 46

72 20

78 20

7.25 T = 390 years, R = 12% 7.26 Re= 0.603 7.27 (a) Ta = 10 years (b) Tb = 190 years 7.29 4908 m3/s 7.30 T = 247 years; xt = Chf = 26700 m3/s; Caf = 34,710 m3/s; Safety margin = 8010 m3/s

+D=FJAH& 8.1

Time (h) 3

Q (m /s) Elevation

(300.0 +) m

3

6

0 1 10 0.0 0.30 0.45

9

12

15

27.6 38.29 41.88 0.95 1.17 1.24

18

21

24

27

40.26 35.35 29.30 23.27 1.21 1.11 0.99 0.87

Answers

8.2

Time (h)

3

Q (m /s) Elevation

(300.00 +) m

8.3

8.5

3

6

9

62.38 m, 55.21 m3/s, 4.8 m3/s Time (h) Q (m3/s) Elev. (200.0 +) (m)

Time (h) Q (m3/s) Time (h) Q (m3/s)

8.7

8.9

15

18

21

24

27

60.84 39.41 38.25 45.86 50.92 49.53 43.81 39.91 32.17 25.08 1.50 1.19 1.17 1.29 1.36 1.34 1.26 1.20 1.04 0.90

8.4 2 h 25 min

0 0 0

2 6.67 0.67

4 6 8 10 12 14 17.78 27.41 28.86 24.38 21.87 18.71 1.78 2.74 2.89 2.44 2.19 1.87

Time (h) 16 18 Q (m3/s) 15.76 12.75 Elev. (200.0 +) (m) 1.58 1.27

8.6

12

" #

0 0

2 4.0

18 20 29.80 19.88

20 9.75 0.98

22 6.75 0.67

24 3.75 0.38

26 075 0.07

4 18.4

6 8 10 12 14 16 43.04 61.82 65.09 59.06 49.43 39.66

22 1193

24 7.16

26 4.29

28 2.58

30 1.55

32 0.93

8.8 21 h, 35 m3/s

K= 10.0 h; x = 0.3 Time (h)

6

12

18

24

30

Q (m3/s)

35.00

29.94

25.49

28.91

41.14

69.49

8.10 Time (h)

4

8

12

16

20

24

28

Q (m /s)

8

8

12

21

25.5

25.25

22.63

18.81

8.11 Time (h) Q (m3/s)

0 10

3 13.91

6 24.63

9 35.48

12 41.55

15 44.08

18 43.99

21 41.97

Time (h) Q (m3/s)

24 38.53

27 34.02

30 28.73

3

8.12 Time (h)

IUH Ord. (m3/s) 1-h UH ord. (m3/s) Time (h) IUH Ord. (m3/s) I-h UH ord. (m3/s)

0 0 0

2 3 4 5 6 7 13.07 17.32 28.10 34.18 33.55 30.75 7.92 15.19 22.71 31.14 33.86 32.15

8 9 10 11 12 13 14 27.67 24.90 22.41 20.17 18.16 16.34 14.71 so on 29.21 26.29 23.66 21.29 19.16 17.25 15.52 so on

b æb ö 8.14 Q = b t – ç - I 0 ÷ e–at – èa ø a

8.13 3 h, 0.6 m3/s

8.15

1 2.78 1.39

Time (h) (h)

u(t) in (cm/h)

u(t) (m3/s)

0 3

0 0.00211

0 2.93

Time (h)

u(t) (cm/h)

33 36

0.01889 0.01487

u(t) (m3/s) 26.25 20.67 (Contd.)

" $ Engineering Hydrology (Contd.) 6 9 12 15 18 21 24 27 30

8.17

Time (h) 0 1 2 3 4 5 6 7 8 9

8.18

0.01022 0.02092 0.03007 0.03563 0.03734 0.03596 0.03256 0.02812 0.02340

14.20 29.08 41.08 49.52 51.90 49.99 45.26 39.09 32.52

39 42 45 48 51 54 57 60 63

0.01147 0.00869 0.00648 0.00477 0.00347 0.00250 0.00178 0.00126 0.00089

15.94 12.08 9.01 6.63 4.82 3.47 2.48 1.75 1.23

IUH u(t) (m3/s)

1-h UH (m3/s)

Time (h)

IUH u(t) (m3/s)

1-h UH (m3/s)

0 25.4 69.1 97.2 104.3 96.4 81.1 64.0 48.1 34.9

0 12.68 47.25 83.17 100.73 100.32 88.75 72.56 56.07 41.54

10 11 12 13 14 15 16 17 18 20

24.6 17.0 11.5 7.6 5.0 3.2 2.1 1.3 0.8 0.525

29.78 20.80 14.22 9.55 6.32 4.13 2.67 1.71 1.08 0.68

Time (h)

u(t) in (m3/s)

Time (h)

u(t) in m3/s

0 2 4 6 8 10 12 14 16 18 20

0.000 2.242 7.692 12.857 16.008 16.962 16.228 14.471 12.255 9.978 7.876

22 24 26 28 30 32 34 36 38 40 42

6.062 4.571 3.386 2.472 1.782 1.270 0.896 0.627 0.435 0.300 0.206

8.19 n = 4.18, K = 3.35 h

+D=FJAH' 9.1 9.2 9.4 9.6 9.9 9.11

S = 16.34%, RD of solids = 2.517 (a) 4125 m3/day (b) 44.175 m 9.3 1.92 cm/s (a) 3.816 ´ 10–3 (b) –1.l2% 9.5 156.459 m 31.46 m/day 9.7 1.73 m 9.8 4.6 years 3.2 m3/day/m length (i) R = 6 ´ 10–4 m3/day/m width (ii) hm = 5.196 m (iv) q1 = 0.18 m3/day/m width (iii) qo = –0.06 m3/day/m width

Answers

" %

9.12 a = 1978.4 m, qa = –1.0842 m3/day/m width, qb = 1.108 m3/day/m width 9.13 2532 lpm 9.14 1716 lpm; (a) 9.5% increase (b) 100% increase (c) 50% inrease 9.15 11.17 m/day 9.17 2556 lpm, 10.54 m 9.18 K = 25.8 m/day; T = 645 m2/day, sw = 10.78 m 9.19 hA = 10.784 m, hB = 10.853 m; (Re)PW = 2.653, (Re)A = 0.0148, (Re)B = 0.00917 9.20 (a) 1159 lpm (b) 570 lpm 9.21 7.78 m/day 9.22 2303 m/day 9.23 1512 lpm 9.24 (a) 17.80 m (b) T = 136.5 m2/day (c) 29.33 m (d) 65.2 m and 86.1 m 9.25 (i) 0.943 h–1 (ii) 46.3 m3/h (ii) 5.96 m3/h 9.26 (i) 0.3066 h–1 3 9.27 36.0 m /h 9.28 T = 105 m2/day; S = 1.976 ´ 10–4 9.29 Q = 1611 lpm 9.30 (i) s = 3.3 m, (ii) s = 4.3 m 9.33 T = 28.1 m2/h 9.31 1.234 m 9.32 S = 4.06 ´ 10–4; T = 36.87 m2/h

+D=FJAH 10.1 10.2 10.3 10.5 10.8 10.10 10.11

10.13

(i) 4.17 ha-m/100 sq. km/year (ii) 10.32 ha-m/100 sq. km/year p = 0.679, W = 1529 kg 10.4 7% under prediction WT1 = 1199.65 kg/m3, WT25 = 1261.2 kg/m3 1160 kg/m3 10.6 730 kg/m3 10.7 102 years. 83 years. 10.9 196 years (a) 9.75 M. Tonnes/year; (b) 875 ppm T35 = 22 years 10.12 m = 3.2 Sl. No.

Elevation (m)

1 2 3 4 5 6 7 8 9 10 11 12 13

350.52 365.76 381.00 396.24 400.00 411.48 426.72 441.96 457.20 472.44 487.68 502.92 512.06

10.14 Elevation (m) Reservoir Area after 10 years (ha) Capacity after 10 years (ha.m)

Final Reservoir Area (ha) 0.0 0.0 777.3 1807.9 2112.0 2871.5 3720.0 4632.7 6059.1 7921.4 10435.7 13325.1 15378.0

106.68 109.73 112.77

0 0

Final Reservoir Capacity (ha.m)

256.65 1194.8 396

2922

0 0 4351 25201 35132 59481 110148 172661 256023 364372 505672 682193 817966

115.82

118.88

121.92 124.97

1176.8

2618.8

3881.8 5741.8

7490

14128

23967 32711

INDEX

A.N. Khosla 182 Abbreviations 413, 414 Abstractions 59 Actual Evapotranspiration (AET) 69, 76 Additional References 413 adjustment curve 128 Aeration zone 320 Agricultural drought 176 AI anomaly 177 albedo 71 AMC 156 Annual rainfall 19 series 254 time series 144 Answers 417 Answers to Problems 418 Antecedent Moisture Condition 156 Anticyclones 15 applied hydrology 1 Approximate methods 296 aquiclude 321 Aquifer 321 Properties 323 aquifuge 321 aquitard 321 Area Increment Method 398 area of influence 343 Area-Velocity Method 101, 109 aridity index 177 Arithmetical-Mean Method 34 artesian aquifer 322 Arthashastra 9 Artificial Recharge 357 Attenuation 290 Automatic Stage Recorders 102 Backwater Effect 127 Bar Chart 32 Barlow’s Tables 148 barometric efficiency 333 Base Flow 140 Base Flow Separation 202

basin lag 225 Bed load 379 material load 379 Binnie’s Percentages 148 Blaney-Criddle Formula 74 bottomset beds 386 Brihatsamhita 9 broad-crested weirs 119 Bubble Gauge 103, 104 Calibration 106 equation 106 capacity—Inflow ratio 387 Capillary Fringe 321 Cascade of Linear Reservoirs 301 cascade of reservoirs 301 Catchment Area 3 Central Simple Moving Average 32 Central Water Commission (CWC) 10 cetyl alcohol 68 Channel Erosion 375, 379 Improvement 311 routing 280 Check dams 181, 404 Chemical Films 68 method 113 Chow’s method 351 Clark’s Method 298 Class A Evaporation Pan 61 Classification of Reservoirs 391 Climatic Factors 196, 198 Cloud seeding 178 Coefficient of Permeability 324, 325 runoff 246 skew 263 variation 20 Colorado Sunken Pan 62 Complete Numerical Methods 296, 297 Complex hydrograph 196, 197 Storm 215

Index Compressibility of Aquifers 330 the pores 331 water 331 Conceptual Hydrograph 297 modelling 297 Zoning 312 cone of depression 343, 354 Confidence Limits 261 confined aquifer 322, 334, 351 Confined Flow 344 Consolidated material 326 constant fall 128 Constant Rate Injection Method 114 constant-head permeameter 327 consumptive use 69 continuity equation 299 Continuous Simulated Models 155 Contour Bunds 180 Contour Ridges 180 control 122 section 118 Convective Precipitation 15 Conversion Factors 416 Conveyance Method 130 convolution integral 233 Crest Segment 198, 199 critical 349 depression head 349 Storm 270 Crop Management Factor 377 Cup-type Current Meter 105 Current Meters 105 Curve Number (CN) 155 CWC 133, 183, 184, 268, 403 Cyclone 14 DAD analysis 38 Daily Rainfall of India 50 Darcy’s Law 324 delayed interflow 140 demand line 167 density currents 387 Density of Sediment Deposits 388 dependability value 144 depletion curve 195 Deposition Process 386 Depression Storage 78, 79 Depth-Area Relation 37 Depth-Area-Duration Relationships 37 Derivation of IUH 234 Design Flood 267 Life 403 Storm 269

desilting 405 Detention Reservoirs 310 deterministic watershed simulation 153 DGPS 385 Dhruv Narayan et al.’s Equation 386 Dickens Formula 251 diffusion equation 334 dilution method 113 Dilution techniques 101, 113 Direct Runoff 140 direct runoff hydrograph (DRH) 203 discharge-frequency curve 163 Distribution Graph 224 Distribution of Sediment 391 divide 4 Doppler-type 23 Double-mass curve technique 27 Double-ring Infiltrometer 83 Drainage Density 197 drawdown 343 Test 353 DRH 203 Drizzle 14 Drought Management 178 Droughts 175 Drying Process 151 Duhamel integral 233 Dupit’s Assumption 335 Flow with Recharge 337 parabola 340 Dynamic resource 361 echo-depth recorder 109 Economic Life 403 Effective Rainfall (ER) 203 effective rainfall hyetograph (ERH) 203 effluent streams 323 Electromagnetic method 101, 115 Empirical Area Reduction Method 393 Empirical Equations 147, 385 Formulae 251 Empirical method 245 Energy Balance in a Water Body 65 Energy-Budget Method 65 engineering hydrology 1 Envelope Curves 252 enveloping curves 252 ephemeral 142 stream 143 equation of continuity 281 Equivalents 416 ERH 203 Erosion 374 Problem 405 Processes 374

" '

"! Index Estimation of Missing Data 26 Evacuation and Relocation 313 Evaporation 59, 185 Equations 63 Process 59 Evaporimeters 60 Evapotranspiration 59, 68, 69 Equations 70 Excess rainfall 203 rainfall (ER) 206 rainfall hyetograph 203 explicit method 297 Extrapolation of Rating Curve 129 Extratropical Cyclone 15 F-test 267 Factors Affecting Erosion 375 fall (F) 127 falling-head permeameter 327 FAO Penman-Monteith method 74 Field capacity 69, 70 Field Plots 70 Float-Gauge Recorder 102 Floats 105, 108 Flood control 309 Flood Control in India 313 Flood Discharge by Slope-Area Method 121 Flood Forecasting 312 Frequency 253 hydrograph 212, 280 Insurance 313 management 309 peak 245 Plain Zoning 311 proofing 313 Routing 280 walls 311 Flood-frequency studies 245 Flooding Type Infiltrometers 83 Floodwater Farming 180 Harvesting 180 Floodways 311 Flow 182 Duration Curve 163, 382 measuring structures 118 Flow–Duration Curve 163 Flow-Mass Curve 166 Flumes 119 foreset beds 386 constants 332 loss 356 Forms of Precipitation 13

Frequency 254 of Point Rainfall 39 Studies 266 Front 14 Gamma Function 302 Gauging site 109 Geologic Formations 330 GIS 155 Glaze 14 Goodrich Method 286 Granular material 326 Green–Ampt Equation 85 Gross erosion 375 Groundwater 320 Development 362 Monitoring 365 Resource 361 GSSHA 155 Guidelines for Design of Floods 268 Gulley Erosion 375 gulp 114 Gumbel Probability Paper 258 Method 255 Hail 14 Hard Rock Areas 359 Heat Storage in Water Bodies 60 History of Hydrology 8 Homogeneity 266 Horizontal-axis Current Meter 106 Horizontal-Axis Meters 105, 106 Horton’s Equation 85 HSP 154 hurricane 14 Hydraulic Method of Flood Routing 296 Hydraulic structures 101 Hydrograph 141, 195 Hydrologic Channel Routing 291 Hydrologic Cycle 1 equation 3 failures 9 Storage Routing 281 Hydrological drought 176 Hydrology 1 Hydrometry 101 Stations 131 Hyetograph 31 of the Storm 48 hyetometer 20 IDF 269 IMD 50 implicit method 297

Index incidental recharge 357 India Meteorological Department (IMD) 10 Indirect Methods 117 Infiltration 2, 80 Capacity 81 gallery 368 Indices 92 Model 81 Inflow Design Flood 269 influent streams 323 Inglis and DeSouza Formula 152 Inglis Formula 251 Initial Loss 78 Instantaneous Unit Hydrograph 232 integration method 114 Inter-Rill Erosion 374 Interception 79 loss 79 process 78 interflow 139 Intermediate Zone 321 intermittent 142 stream 143 intrinsic permeability 326 irrigation tanks 181 ISI Standard Pan 61 iso-pluvial 46 isochrone 274 isohyet 35 Isohyetal Method 35 isopleths 76 Isopluvial Map 46 IUH 232 Joglekar’s Equation 386 Khosla’s equation 386 Formula 152 Kirpich Equation 246 Kostiakov Equation 85 KWM 154 lag 290 lag time 225 Lake evaporation 62 Land use/cover 156, 157, 198 Laplace equation 334, 336 Length of Reach 115 Levees 310 Level Pool Routing 282 Life of a Reservoir 400 Limitations 223 Linear channel 297 reservoir 292, 297

"!

Response 206 storage 292 log normal distribution 263 Log-Pearson Type III Distribution 263 Long-base weirs 119 Loop Rating Curve 128 lsochrone 298 Lysimeters 70 Macro Catchment System 180 Maintainable Demand 169 Manual Gauges 102 Mass Curve of Rainfall 31 Mass-Transfer Method 66 Maximum Depth-Duration Relationship 43 Maximum Intensity-Duration Relationship 43 Maximum Intensity-Duration-Frequency Relationship 43, 44 maximum yield 349 mean annual flood 258 Measurement 379 Infiltration 82 Precipitation 20 Velocity 105 Mechanical Covers 68 Meteorological drought 176 radars 23 method of characteristics 297 method of mid-sections 110 Method of superposition 216 Meyer’s Formula 63 MIKE SHE 155 model 153 Modelling Infiltration Capacity 84 Modified Pul’s Method 282 Modified Universal Soil Loss Equation (MUSLE) 378 Moisture availability index (MAI) 177 monsoon 16 trough 16 Monthly Rainfall of India 50 Monthly Variation of PET 77 Movement of Sediment 381 Moving average 32 moving means 32 Moving-Boat Method 112 multi-path gauging 117 Muskingum Equation 292 Routing Equation 295 MUSLE 378 Nalabunds 181 Nash’s Conceptual Model 301

"!

Index

National Remote Sensing Agency (NRSA) 10 Natural 182 Flow 140 Recharge 357 Natural-Syphon Type 22 Negarim Micro Catchments 180 Non-structural methods 309 Nonrecording Gauges 20 normal annual percipitation 26 normal rainfall 26 ombrometer 20 Onset of Monsoon 16, 17 Open Wells 349 Orographic Precipitation 15, 16 overland flow 139 B-index 92 B index for practical use 95 Pan Coefficient Cp 62 Partial Duration Series 266 Penman’s Equation 71 percolation tanks 181 perennial 142 rivers 323 stream 142 permanent 122 Control 122 wilting point 69, 70 permeameter 327 PET = Potential evapotranspiration 177 Philip’s Equation 85 phreatic surface 335 physiographic factors 196 pigmy meters 106 plateau gauging 114 Plotting Position 40 Plotting Position Formulae 41 pluviometer 20 PMP 269 Point Rainfall 31 Porosity 323 Post-Monsoon 18 potential condition 78 potential evapotranspiration (PET) 69 precipitation 13 Prism storage 291 Probable Maximum Flood (PMF) 267 Probable Maximum Precipitation (Pmp) 48 prompt interflow 140 quick return flow 139 quick-response flow 202 Radar Measurement of Rainfall 23

Radioactive materials 114 radius of influence 343 Rainfall 20 Data In India 50 Erosivity Factor 376 Simulator 84 Rainfall–Runoff Correlation 145 raingauge 20 Raingauge Network 24 Rashtriya Barh Ayog 313 rating equation 124 Rational Formula 163 Method 245 ravine reclamation structures 404 recession constant 199 Recession Limb 199 Recharge 321, 337, 357 Recharge from Irrigation 360 Recording Gauges 21 recovery 344, 354 of Piezometric Head 354 Recovery Test 355 recuperation 344 Test 349 recurrence interval 39 Reduction in Sediment Yield 403 Reference Crop Evapotranspiration 74 Regional Flood Frequency 266 Reservoir 391 Evaporation 66 routing 280 Sedimentation 374, 407 Problems in India 405 Sedimentation Control 403 residence time 7 residual drawdown 354 retention 324 return flow 144, 182 return period 39, 254, 255 Return Periods 41 Rill Erosion 375 Rising Limb 198 Risk and Reliability 271 Rod float 109 Roof Top Water Harvesting 179 Routing 299 RTWH 179 Runge-Kutta method 289 Running’s Method 124 Runoff 2, 139 Characteristics 142 Coefficient 6, 247 isochrone 298 Volume 143, 149 Ryves Formula 251

Index S-curve 216 S-hydrograph 218 safe yield 349, 361 Safety Factor 271 margin 271 Saturated Formation 321 Zone 80, 320 Scientific hydrology 1 scouring sluices 404 SCS Dimensionless Unit Hydrograph 229 SCS Triangular Unit Hydro-graph 229 SCS-CN Equation for Indian Conditions 158 SCS-CN Method 155 secondary gauge 127 Sediment Delivery Ratio 376, 385 Sediment Rating Curve 382 Sediment Yield 375, 382 sediment–production rate 376 seepage 322 Seepage from Canals 360 Sequent Peak Algorithm 169, 171 Shape of the Basin 196 Sheet Erosion 376 Shifting Control 122, 126 Simple (Tube Type) Infiltrometer 83 single-path gauging 117 Size 197 Classification of Dams 268 Sleet 14 Slope 197 Slope area method 101, 118, 119 Snow 14 Gauges 24 Tubes 24 Snowfall 23 Snyder’s Method 225 Soil and Water Conservation 404 Soil Erodibility Factor 377 Texture 248 type 156 Soil Water Zone 321 Solar Radiation 72 Sources of Data 10 South-West Monsoon 16 specific capacity 350, 357 storage 332 Yield 324 Specific Yield Method 358 Spillway Design Flood 267 Spreading of Water 181 springs 322 SSARR 154

St Venant equations 281, 296 Staff Gauge 102 Stage for Zero Discharge 124 Stage Hydrograph 104 Stage-Discharge Relationship 122 standard current meter method 110 Standard Project Flood (SPF) 267 Standard SCS-CN equation 158 Stanford Watershed Model (SWM) 154 Static resource 361 station rainfall 31 Station-year method 56 stationary 266 stearyl alcohol 68 stemflow 79 Stilling well 103 storage components 3 Storage Recession Curve 201 Storage Reservoirs 309 Storage Structures Systems 181 Storativity 332 storm hydrograph, flood hydrograph 195 loss rate 211 seepage 139 Strange’s Tables 149, 151 Stratification 327 stream flow 2 Measurement 101 Structural measures 309 Submerged Flow 119 subsurface flow 320 storm flow 139 water 320 Sudden-injection Method 113 Sunshine Hours 73 Supporting Cultivation Practice 378 surface float 109 Surface of Entry 82 surface runoff 139 Surface Water Resources of India 182 Suspended load 379 SWM-IV 154 Symons’ gauge 20 Synthetic unit Hydrograph 225 t-test 267 Telemetering Raingauges 22 Test for Consistency of Record 27 Theodolites 385 Thiem’s equation 345 Thiessen polygons 34 Thiessen-Mean Method 34 Thin-plate structures 119 Thornthwaite Formula 76

"!!

"!" Index through flow 139 throughfall 79 Tile drain problem 340 Time Invariance 206 Time of Concentration 246 time series 266 Time–Area Curve 298 Time-area Histogram 299 time-homogeneous 266 Tipping-Bucket Type 21 top set beds 386 Topographic Factor 377 Total Station 108, 385 towing tank 106 Tracers 114 transmission zone 80 Transition Zone 80 transmissibility 326, 355 Transmission Zone 80 Transpiration 2, 68 transportation (flow) components 3 Trap Efficiency 386, 387 Tropical cyclone 14 turbidity currents 387 Type curve 351 typhoon 14 ultimate infiltration capacity 85 Ultrasonic Method 101, 116 unconfined aquifer 321 Flow 335, 346 Unit Hydrograph 205 unit-hydrograph method 205 Universal Soil Loss Equation (USLE) 376 Unsteady Flow 343, 351 Unsteady-Flow Effect 128 US Geological Survey Floating Pan 62 US National Weather Service (USNWS) method 54 Useful Life 403 Useful Websites 413 USLE 378 Utilizable Dynamic Groundwater Resources 185 Utilizable Groundwater 365 Water Resources 184

Variable Demand 170 Vegetative cover 248 Vertical-axis Current Meter 105 Vertical-axis meters 105 virgin flow 140 W-Index 94 wading 108 wash lines 121 load 379 Water Budget Equation 3, 4 water divide 339 Water Harvesting 179 Harvesting Structures 360 Table 322 table aquifer 321 Year 142 Water-Budget Method 64 Water-depth recorder 103 watershed 3, 382 Erosion 385 Management 311 Simulation 144, 153 Weather Systems 14 Wedge storage 291 Weibull formula 40 Weighing-Bucket Type 22 weighting factor 292 well function 351 Loss 356 Wells 343 Wetting Front 80 Process 150 Zone 80 Wire Gauge 102 Withdrawal of Monsoon 17 WMO Criteria for Hydrometry Station Density 132 working head 349 World Water Balance 6 Year books 133 Yield 143, 324

(K Subramanya) Engineering Hydrology - PDFCOFFEE.COM (2024)

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