This document provides information about a training module on understanding stage-discharge relations being conducted by the Central Water Commission of India. The training is aimed at middle level engineers and will cover topics like correlation and regression analysis, classification of controls, characteristics of rating curves, extrapolation of rating curves, and shifts in discharge ratings. The module will be 90 minutes long and use methods like lectures, discussions and questioning. The objectives are to help officers understand stage-discharge relations and impart this training to supervisors and junior staff.
Overbank Flow Condition in a River SectionIDES Editor
When the flows in natural or man made channel
sections exceed the main channel depth, the adjoining
floodplains become inundated and carry part of the river
discharge. Due to different hydraulic conditions prevailing in
the river and floodplain of a compound channel, the mean
velocity in the main channel and in the floodplain are different.
This leads to the transfer of momentum between the main
channel water and that of the floodplain making the flow
structure more complex. Results of some experiments
concerning the overbank flow distribution in a compound
channel are presented. Flow sharing in river channels is
strongly dependant on the interaction between flow in the
main channel and that in the floodplain. The influence of the
geometry on velocity and flow distribution and different
functional relationships are obtained. Dimensionless
parameters are used to form equations representing the over
bank flow sharing in the subsections. The equations agree
well with experimental discharge data and other published
data. Using the proposed method, the error between the
measured and calculated discharge distribution for the a
compound sections is found to be the minimum when compared
with that using other investigators.
Stream Gauging: Necessity; Selection of gauging sites; Methods of discharge measurement; Area-Velocity method; Venturi flume; Chemical method; weir method; Measurement of velocity; Floats Surface float, Sub–surface float or Double float, Twin float, Velocity rod or Rod float; Pitot tube; Current meter; Working of current meter; rating of current meter; Measurement of area of flow; Measurement of width - Pivot point method; Measurement of depth Sounding rod, Echo- sounder.
Overbank Flow Condition in a River SectionIDES Editor
When the flows in natural or man made channel
sections exceed the main channel depth, the adjoining
floodplains become inundated and carry part of the river
discharge. Due to different hydraulic conditions prevailing in
the river and floodplain of a compound channel, the mean
velocity in the main channel and in the floodplain are different.
This leads to the transfer of momentum between the main
channel water and that of the floodplain making the flow
structure more complex. Results of some experiments
concerning the overbank flow distribution in a compound
channel are presented. Flow sharing in river channels is
strongly dependant on the interaction between flow in the
main channel and that in the floodplain. The influence of the
geometry on velocity and flow distribution and different
functional relationships are obtained. Dimensionless
parameters are used to form equations representing the over
bank flow sharing in the subsections. The equations agree
well with experimental discharge data and other published
data. Using the proposed method, the error between the
measured and calculated discharge distribution for the a
compound sections is found to be the minimum when compared
with that using other investigators.
Stream Gauging: Necessity; Selection of gauging sites; Methods of discharge measurement; Area-Velocity method; Venturi flume; Chemical method; weir method; Measurement of velocity; Floats Surface float, Sub–surface float or Double float, Twin float, Velocity rod or Rod float; Pitot tube; Current meter; Working of current meter; rating of current meter; Measurement of area of flow; Measurement of width - Pivot point method; Measurement of depth Sounding rod, Echo- sounder.
A pumping test is a field experiment in which a well is pumped at a controlled rate and water-level response (drawdown) is measured in one or more surrounding observation wells and optionally in the pumped well (control well) itself; response data from pumping tests are used to estimate the hydraulic properties of aquifers, evaluate well performance and identify aquifer boundaries.
In this study the kinematic wave equation has been solved numerically using the modified Lax
explicit finite difference scheme (MLEFDS) and used for flood routing in a wide prismatic channel and a nonprismatic
channel. Two flood waves, one sinusoidal wave and one exponential wave, have been imposed at the
upstream boundary of the channel in which the flow is initially uniform. Six different schemes have been
introduced and used to compute the routing parameter, the wave celerity c. Two of these schemes are based on
constant depth and use constant celerity throughout the computation process. The rest of the schemes are based
on local depths and give celerity dependent on time and space. The effects of the routing parameter c on the
travel time of flood wave, the subsidence of the flood peak and the conservation flood flow volume have been
studied. The results seem to indicate that there is a minimal loss/gain of flow volume whatever the scheme is.
While it is confirmed that neither of the schemes is 100% volume conservative, it is found that the scheme
Kinematic Wave Model-2 (KWM-II) gives the most accurate result giving only 0.1% error in perspective of
volume conservation. The results obtained in this study are in good qualitative agreement with those obtained in
other similar studies.
Quick tutorial of how to conduct a bridge scour computation within HECRAS. Characteristics of stream stability fundamentals are also discussed. Abutment, pier, and contraction methodologies from HEC 18 are summarized. Tips to avoid common mistakes are provided. Helpful data sources to assist design are suggested.
A pumping test is a field experiment in which a well is pumped at a controlled rate and water-level response (drawdown) is measured in one or more surrounding observation wells and optionally in the pumped well (control well) itself; response data from pumping tests are used to estimate the hydraulic properties of aquifers, evaluate well performance and identify aquifer boundaries.
In this study the kinematic wave equation has been solved numerically using the modified Lax
explicit finite difference scheme (MLEFDS) and used for flood routing in a wide prismatic channel and a nonprismatic
channel. Two flood waves, one sinusoidal wave and one exponential wave, have been imposed at the
upstream boundary of the channel in which the flow is initially uniform. Six different schemes have been
introduced and used to compute the routing parameter, the wave celerity c. Two of these schemes are based on
constant depth and use constant celerity throughout the computation process. The rest of the schemes are based
on local depths and give celerity dependent on time and space. The effects of the routing parameter c on the
travel time of flood wave, the subsidence of the flood peak and the conservation flood flow volume have been
studied. The results seem to indicate that there is a minimal loss/gain of flow volume whatever the scheme is.
While it is confirmed that neither of the schemes is 100% volume conservative, it is found that the scheme
Kinematic Wave Model-2 (KWM-II) gives the most accurate result giving only 0.1% error in perspective of
volume conservation. The results obtained in this study are in good qualitative agreement with those obtained in
other similar studies.
Quick tutorial of how to conduct a bridge scour computation within HECRAS. Characteristics of stream stability fundamentals are also discussed. Abutment, pier, and contraction methodologies from HEC 18 are summarized. Tips to avoid common mistakes are provided. Helpful data sources to assist design are suggested.
Geography notes Hydrology, Atmosphere, Weathering, Population and Migration
Casestudies aren't included - sorry. Hope these are helpful. Good luck everyone with your exams.
Case study of Uttarakhand Flood Disaster 2013 - by Narendra YadavNarendra Yadav
this is the presentation about the flood that occured in uttrakhand in 2013
this is the case study for uttrakhand disaster
It you liked the ppt please just post the comment below
Guyz we have worked very hard for this ppt .... it deserve at least 1 COMMENT
https://www.youtube.com/watch?v=H79x9wztngM
https://www.tvlyrics.in
1
KNE351 Fluid Mechanics 1
Laboratory Notes
Broad-Crested Weir
This booklet contains instructions and notes for the experiment listed above.
Additional material relating to laboratory work will be delivered during the
course. The expectations regarding lab work and reporting are described in a
separate document,‘KNE351. FLUIDMECHANICS: Laboratory Method and
Reporting’, which will also be circulated at the beginning of the course. It is
expected that all students study these notes and complete the pre-lab component
prior to the laboratory session. An overview of the laboratory equipment will
be provided at the beginning of each session.
A D Henderson
2
1. Learning Objectives
1. Observe and understand the behaviour of a real fluid flowing over a broad-crested weir,
2. Model this behaviour employing the Continuity and Bernoulli (Energy) Principles to
predict the flow rate from depth measurements.
3. Evaluate these predictions by comparing with measured values and use Specific Energy
to explain the changing nature of the flow over the weir.
2. Introduction
The theory of non-uniform flow in channels is covered by the course text, by many other fluid
mechanics texts, and by several web sites.
The specific energy, E, is the energy at a channel cross-section referred to the base of the
channel (in contrast to the Bernoulli equation, which is referred to a fixed horizontal datum).
The expression given for E is actually an approximation valid for small bed slopes. You've
measured the flume slope, and should examine this approximation in your report. A hydrostatic
pressure distribution is assumed, and you should also examine the validity of this assumption. If
the streamlines are not parallel, then the accelerative forces will modify the pressure - depth
relationship.
In general, two conjugate flows depths satisfy the specific energy equation for a given value of
the specific energy. The greater depth is associated with subcritical flow, and the shallower
depth with supercritical flow. At the critical depth the conjugate depths are equal, and the
discharge for the given specific energy is a maximum.
Broad crested weirs are used as a method of flow measurement in open channel flows. If the
weir is sufficiently high and long, the free surface will drop to critical depth. If the height of
the upstream flow is measured, then the flow rate can be determined.
3
3. Apparatus
• Water flume comprising of pump, control valve, venturi and v-notch flow meters,
downstream control gate.
• depth gauges
• 2 vertical water manometers
• 2 total head tubes
4. Preparation
Examine and sketch the layout of the channel and associated flow measuring equipment.
Measure the channel width and note significant geometrical parameters of the nozzle venturi
meter and V-notch weir. Note the directions of readings of all measuring scales.
a. Measure the channel, weir dimensions, a.
DESIGN A HYDRAULIC STRUCTURE USING THE RAINFALL INTENSITY- DURATION- FREQUENC...IAEME Publication
A hydrologic analysis is an essential prerequisite for any project, is used to the evaluation of the watershed area for a stream and is used to determine the design discharge or the amount of runoff the culvert should be designed to convey. In this paper the relationship between the intensity duration-
and frequency of rainfall are used to obtain the value of discharge to design a pipe culvert for Najaf station in Iraq, from the relationship between Intensity-duration-frequency (IDF) curves, the values of intensity for 10, 100 years return periods with 15, 30, and 60 min. durations are obtained and discharge values are obtained from multiplied the catchment area for Najaf station by the values of intensity for obtaining.
Pumping Tests are conducted to examine the aquifer response, under controlled conditions, to the abstraction of water. Hydrogeologists determine the hydraulic characteristics of water-bearing formations, by conducting pumping tests. A pumping test is a practical, reliable method of estimating well performance, well yield, the zone of influence of the well and aquifer characteristics. There is a procedure for conducting pumping tests in wells. This lesson highlights the prevailing methods adopted while conducting pumping tests.
IJRET : International Journal of Research in Engineering and Technology is an international peer reviewed, online journal published by eSAT Publishing House for the enhancement of research in various disciplines of Engineering and Technology. The aim and scope of the journal is to provide an academic medium and an important reference for the advancement and dissemination of research results that support high-level learning, teaching and research in the fields of Engineering and Technology. We bring together Scientists, Academician, Field Engineers, Scholars and Students of related fields of Engineering and Technology
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1. GOVERNMENT OF INDIA
CENTRAL WATER COMMISSION
CENTRAL TRAINING UNIT
HYDROLOGY PROJECT
TRAINING OF TRAINERS
IN
HYDROMETRY
UNDERSTANDING STAGE -DISCHARGE
RELATIONS
M.K.SRINIVAS
DEPUTY DIRECTOR
CENTRAL TRAINING UNIT
CENTRAL WATER COMMISSION
PUNE - 411 024
2. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.2
TABLE OF CONTENTS
1. Module Context
2. Module Information
3. Session Plan
4 Instructors Note
5 Suggestions for testing
6. Overhead Sheets
3. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.3
1. MODULE CONTEXT
This module is a part of the 'Training in Hydrometry’ for middle level
engineers. This module is one of the two modules on 'Stage-Discharge
Relations’. The two modules are :
Module Code Subject Contents
1. Understanding Stage -
Discharge Relation
− Introduction to Stage -
Discharge ratings, and
Correlation and Regression
− Classification of controls
− Characteristics and
Extrapolation of rating curves
− Shifts in discharge ratings
2. How to analyse Stability of
SD relation
− Fitting of curve for S-D
relations
− Testing the significance of
curve fitting
− Drawing of confidence limits
− IS Code procedures
4. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.4
2. MODULE INFORMATION
Title : Understanding Stage-Discharge
Relation
Target Group : Middle Level Engineers
Duration : 90 minutes
Objectives : After training, the officers would be able
to understand the concept of Stage-
Discharge Relation and impart training
to Supervisors and Junior Staff
Key Concepts : − Correlation and Regression
− Method of least squares
− Classification of controls
− Rating Curve Extrapolation
− Shifts in ratings
Training methods : Lecture, discussions & questioning
Training aids : Overhead Projector, Transperancies,
blackboard, Examples of Regression
Analysis
Handout : Main text and Example
5. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.5
3. SESSION PLAN
Activity Time
1. Introduction to Stage - Discharge Relations 5 minutes
2. Discuss about correlation & Regression
analysis
5 minutes
3. Talk about classification of controls 10 minutes
4. Brief discussion 5 minutes
5. Briefly explain about characteristics of
Rating Curve
10 minutes
6. Discuss the example given in handout 10 minutes
7. Details about methods of extrapolation 20 minutes
8. Explain about shits in discharge ratings 10 minutes
9. Questions & discussions for testing 15 minutes
90 minutes
6. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.6
INTRUCTORS NOTE
7. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.7
UNDERSTANDING STAGE-DISCHARGE RELATIONS
1.0 INTRODUCTION
'Discharge Rating' is usually defined as the relation between the river stage and
discharge. The terms 'rating', 'rating curve', 'station rating', and 'stage-discharge relation ' are
synonymous with the term 'discharge rating'.
The measured discharge is plotted against the corresponding stage to define the
rating curve; the plot could be in rectangular coordinates or logarithmic. The discharge is
plotted as the abscissa and the stage as the ordinate in rectangular coordinates.
While it is much easier to observe the stages of a river, the discharge observation by
actually measuring the depth and velocity of the flow is cumbersome and expensive. Hence
the data is often collected in the form of stages and is converted into discharge with the help
of an established stage-discharge relation as the data in the form of discharge may be more
meaningful and desired by the users in their analysis. A good and stable stage- discharge
relation is very much essential for estimating the discharges accurately from the observed
stages. Though the World Meteorological Organisation (WMO) recommends a minimum
of ten discharge measurements per year, it may be necessary to have regular daily
observations of stage and discharge simultaneously for an initial period in order to establish
a reliable stage- discharge relation at a hydrological observation station.
2.0 STAGE-DISCHARGE CONTROLS
The stage-discharge relation at a gauging station is often controlled by the section
or reach of the channel down stream of the station gauge line or certain other physical
element. A stage-discharge control could be defined as the physical element or a
combination of elements that control the relation between the stage and discharge at the
section of measurement of the flow. This element could be in the form of a rock outcrop or
a natural riffle, or any other physical feature due to the presence of which the water level on
the upstream side of the section increases and a good stage-discharge relation is obtained.
2.1 Classification of controls
SECTION CHANNEL
NATURAL ARTIFICIAL
PHYSICAL
PARTIAL COMPLETE COMPOUND
FUNCTIONAL
STAGE DISCHARGE CONTROLS
Controls can be classified such as section control, channel control, partial control,
complete control and compound control. These controls could either be natural or artificial.
2.1.1 Section Controls
8. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.8
The section control, as the name indicates is due to the shape of the cross-section.
When the geometry of the cross -section allows the channel to be constricted which could
either be from a local rise in the stream bed or a natural riffle or a rockledge outcrop, the
section control plays a predominant role in stabilising the stage-discharge relation. The
constriction could also be artificial as in the case of manmade encroachment (resulting in
the reduction of the width of the stream), or a constructed weir, or bridge (which reduces the
waterway). Section control also exists when there is a sudden break in the bed slope.
Examples of such control are the head of a cascade or the brink of a waterfall etc. The
section control is usually effective at low discharges and the channel controls take over at
medium and high stages.
2.2 Channel Controls
A channel control is said to exist when the geometry and the roughness of a long
reach of the stream, downstream of the station gauge line, controls the Stage-discharge
relationship. This control usually consists of all the physical features of the channel viz.
size, slope, roughness, alignment, etc., which determine the stage of a river at any given
point of time for a given rate of flow. The length of the channel that is effective as a
control, increases with the discharge and new features that affect the stage-discharge
relation may enter at higher discharges. Generally, the flatter the stream gradient, the longer
the reach of the channel control.
2.3 Partial Controls
A partial control is a control that acts in conjunction with another control in
governing the stage- discharge relation. Such a situation exists where the section control is
the sole control at lower stages and it is the channel control at the higher stages. At
intermediate stages, there is a transition from one control to another and at these stages both
section and channel controls act together as partial controls.
2.4 Complete Controls
A complete control is the one that governs the Stage- Discharge relation throughout
the entire range of stages. Natural existence of such a control is of rare occurence and few
artificial controls may act as complete controls. A section control could be a complete
control if it is a weir, dam, cascade or falls etc., of such a height at which the downstream
condtions do not affect the Stage-discharge relation. A channel control could be a complete
control as in the case of a sand channel that is free of ruffles or bars, or an artificial channel
like concrete lined flood way etc.
2.5 Compound Controls
A compound control is the one in which the stage- discharge relation is governed
by more than one control, each of which may act at different ranges of stages. A common
example is the usual situation where the section control is effective at lower stages, a partial
control at intermediate stages and a channel control at higher stages.
9. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.9
2.6 Artificial Controls
These controls are manmade like a structure built across the stream, or constriction
of the river width due to construction of a bridge or encroachment of the river banks by
dumping waste material etc., which serve as a control for the stage-discharge relation.
Artificial controls like weirs etc., eliminate many of the undesirable characteristics of
natural controls. They are not only permanent but also provide stability to the
stage-discharge relation.
Some of the important attributes that are desirable in an artificial control are:
The control should be permanent and structurally stable.
Excessive seepage under and around the structure should be avoided and if
required, necessary precautions like sheet piling or construction of concrete
cut-off walls should be undertaken.
The crest of the structure should be as high as feasible so that the downstream
conditions do not affect the control at higher stages.
The profile of the crest of the control should be so designed that
a. Small changes in the discharges at low stages should be able to cause
measurable change in the stage.
b. The stage-discharge relation obtained could be extrapolated to peak
discharges with minimum error.
The structure should be designed to be self- cleansing, so that the sediment
being carried by the stream remains undisturbed.
2.7 Correlation and Regression
Both simple and multiple correlation and regression analysis are the oldest
statistical techniques used in hydrology. The main objectives of this analysis are the
transfer of information between points at which the same variable was observed or between
two among several variables observed simultaneously. This includes the completion of
missing data in Hydrology series and the prediction of a variable from the observed one or
several other variables.
Correlation is defined as the association of two or more random variables that only
partly explains the total variations of other random variables involved in the association
equation. The effect of unaccounted or neglected random variables and errors is responsible
for the remaining or unexplained part of the variation. Typical examples of correlative
associations of random variables in hydrology are: Rainfall-runoff, Stage-Discharge,
Sediment load- runoff, oxygen content- water temperature etc.,. An example of multiple
correlation is to define run-off as a function of rainfall characteristics, river basin geometric
properties, soil and vegetation factors, moisture conditions of the basin, and other factors.
Regression represents a mathematical equation expressing one random variable as
being correlatively related to another random variable or to several random variables. All
10. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.10
variables on the right side of this equation do not need to be random variables. The
regression equation may be any function that can be fitted to set of points of observed
variables. The selection of the function to be fitted to points determines the type and the
degree of correlative association. Determining mathematical models of correlative
association of two or more variables, so that the best prediction of one variable can be
obtained from other variable or variables is referred to as regression analysis, and the
models are called regression functions.
3.0 CHARACTERISTICS OF RATING CURVES
The stage-discharge relations are usually developed from a graphical analysis of the
discharge measurements plotted on either rectangular coordinate or logarithmic sheet. The
discharge values are plotted as the abscissa and the corresponding stage values as the
ordinate and a curve (in case of rectangular coordinate plot) or a straight line (in case of
logarithmic plot) is fitted.
Mathematically, the relation that controls the stage- discharge relation is of
the form
Q = C(G-G0)n
where
Q is the discharge (Cumecs)
G is the gauge height (Metres)
G0 is the gauge height for zero discharge (Metres)
C is the station constant
n is the slope of the rating curve
Such an equation plots as a straight line on a logarithmic plot of log(G-G0) Vs
log(Q). Plotting the stage-discharge curve on a log-log plot has its advantages. Since the
shape of the cross section and accordingly the control varies with the stage, the stage-
discharge points plot as straight lines with changing slopes for different ranges of stages
thereby indicating accurately the stage at which the control changes. Also the portion of the
rating curve that is applicable to any range of stage can be linearized for extrapolation or
interpolation. A typical plot of stage-discharge curve on rectangular and logarithmic scale
is shown at Figures 1 and 2 respectively.
11. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.11
DISCHARGE (in Cumecs)
X
Y
STAGE (in Metres)
TYPICAL S-D CURVETYPICAL S-D CURVE
Q = C(G-G0) n
FIGURE 1
L O G (Q )
X
Y
LOG(G-G0
)
A S T A G E D IS C H A R G E R E L A T IO NA S T A G E D IS C H A R G E R E L A T IO N
P L O T T E D O N L O G A R T H M IC S C A L EP L O T T E D O N L O G A R T H M IC S C A L E
log (Q ) = n log (G -G 0) + log C
FIGURE 2
3.1 Determination of stage for Zero Discharge
3.1 1 Trial & Error Method
The most important aspect in plotting the log-log plot is the determination of the
value of ‘G0’ i.e. the gauge for zero discharge. The value of G0 can be determined by trial
and error. If the value of the G0 selected is greater than the actual, the curve on log- log
plot would be concave upwards and on the other hand, if it is less than the actual, the curve
would be concave downwards and the actual value can then be determined by adjusting ' G0'
such that the points plot as a straight line.
3.1.2 Analytical Method
12. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.12
A more objective method to determine the value of G0 is described in Section A-4.9
of IS:2914-1964 "IS Recommendations for Estimation of Discharges by Establishing Stage-
Discharge Relations in Open Channels" which is discussed here.
Select three sets of values namely (G1, Q1), (G2,.Q2) and (G3,Q3) on the rating
curve, on the ordinate scale such that the values Q1, Q2 and Q3 are in geometric progression
i.e.
Q2
2
= Q1 X Q3 --------------------- (1)
The values of G1 , G2 and G3 corresponding to Q1 , Q2 and Q3 are also picked up.
In accordance with the properties of a straight line of the form Q = C (G- G0)n
and
substituting in equation (1) above, it can be derived that
(G2- G0)2
= (G3- G0) x (G1- G0) --------------------------- (2)
Expanding equation (2) and solving for Go yields
G1G3 - G2
2
G0 = ------------------ --------------------------- (3)
G1 + G3 - 2G2
Thus the value of G0 can be computed.
3.1.3 Graphical Method
A graphical solution of obtaining the value of G0 is described now.
As above, three values of discharge in geometric progression are selected. Let the
corresponding points be A,B and C as illustrated in figure 3. Through points A and B
vertical lines are drawn and through points B and C horizontal lines are drawn to meet the
verticals at points D and E respectively. Join ED and BA and extend so that they intersect
at F. Then the ordinate of F is the value of G0.
DISCHARGE (in Cumecs)
X
Y
STAGE(inMetres)
DETERMINATION OF GDETERMINATION OF GOO
BY GRAPHICAL METHODBY GRAPHICAL METHOD
Q1
Q2
Q3
A
B
C
D
E
F
GO
FIGURE 3
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Thus the value of G0 can be obtained by using any of the three methods described above.
4.0 REGRESSION ANALYSIS
After having selected the value of G0, the constants C and n of the mathematical
relation can be determined by statistical method, i.e. regression analysis.
For least square regression, the sum of the squares of the deviations between
Log(Q) and Log (G- G0) should be minimum. Accordingly, it can be shown that
Σ(Y) - N Log (C) - n Σ (X) = O and
Σ(XY) - Σ(X) Log (C) - n Σ(X)2
= O where
Σ(Y) = Sum of all values of Log (Q)
Σ(X) = Sum of all values of Log (G- G0)
Σ(X)2
= Sum of the squares of X
Σ(XY) = Sum of the products of Log(Q) and Log(G- G0)
N = Number of observations
The preparation of the data and solution of the equation is simplified by employing
a tabulation procedure as detailed in the handout .
5.0 EXTRAPOLATION OF RATING CURVES
If the discharge measurements cover the entire range of stages experienced during a
period, and the stage-discharge relation is stable, there is little or no problem in defining the
discharge rating for that period. On the other hand, if, as is usually the case, there are no
discharge measurements to define a part of the curve, then the defined part of the curve
needs to be extrapolated to the highest or lowest stage experienced as the case may be to
find the discharge at that stage. The stage-discharge relation curves are primarily intended
for interpolation and their extrapolation beyond the highest recorded discharge or lowest
recorded discharge may be subject to risk and indefinite errors. Physical factors like
over-bank spills at higher stages, shifts in controls at very low and very high stages, changes
in rugosity coefficients at different stages etc., materially affect the nature of
stage-discharge relationship at the extreme ends and all these factors are to be taken into
account while extrapolating the stage-discharge curve. Such extrapolations are always
subject to error, but these errors can be minimized by proper application of hydraulic
principles and hence it is always better to check the results obtained by more than one
method. Extrapolation of rating curves can basically be classified as "Low flow
extrapolation" and "High flow extrapolation".
5.1 Low flow extrapolation
Low flow extrapolation is best performed on a rectangular co-ordinate graph plot
because the co-ordinates of zero flow can be plotted on such paper. It is to be noted that
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zero flow cannot be plotted on Logarithmic paper. An example of low flow extrapolation is
demonstrated in Fig. 4 where the circled points represent discharge measurements plotted
on the co-ordinate scale of stage vs discharge. The stage for zero flow can be obtained by
field observations or by the method described in the preceding section. After identifying the
stage for zero discharge, the point of zero flow is joined by a smooth curve to the defined part of the
rating curve.
DISCH ARGE (in Cum ecs)
X
YSTAGE(inMetres)
DEFINED
EXAM PLE O F LO W FLO WEXAM PLE O F LO W FLO W
EXTRAPO LATIO NEXTRAPO LATIO N
G O
EX TRAPO LATED
FIGURE 4
5.2 High flow extrapolation
High flow extrapolation is usually complex and great care is to be exercised in arriving at
the extrapolated values. In the following sub-sections different methods of extrapolation are
described and their practical utility is also discussed. It is suggested that the best method
suiting the practical conditions should be selected for extrapolation
5.2.1 Double log extension
This method involves simple extension of the straight line plot on log-log sheet to
the required gauge height and reading the corresponding discharge. This method is usually
not reliable because of the likelihood of change in control at high stages. The change in
control will result in a change in the slope of the straight line plot and the discharge read
from the extended plot of log(G- G0) Vs log(Q) may lead to serious errors in estimating the
peak flows.
This method, due to its simplicity (if log-log plot is readily available) could be used
for obtaining a rough and conservative value of the estimated discharge provided the
control is not changing significantly.
5.2.2 Steven's Method
The Steven's method is based on the equation of steady flow i.e. Chezy's equation
which is
Q = A.C. √R.S. with usual notations
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If C √S is assumed to be constant for a station and D, the mean depth is substituted
for R, then
Q = K.A.√ D where K = C √S
Known values of Q and A√D are plotted on a rectangular coordinate graph and
such plotting usually defines close to a straight line, which can be easily extended for
extrapolation. Values of A√D for the stages above the existing rating can be obtained from
field measurement and used with the extended curve for estimating the discharge. It is important
to note that an abrupt discontinuity in the curve is likely at bankful stages.
5.2.3 Conveyance slope method
This method is based on the equations of steady flow, such as Chezy's or Manning's
equations. These equations can be expressed as
Q = KS 1/2
Where
Q is the discharge
S is the slope and
K is the conveyance
In Manning's equation,
K = 1/n A.R. 2/3
and
in Chezy's equation
K = C.A.R. 1/2
where
A is the area of the cross section
R is the hydraulic radius and
C & n are Chezy's and Manning's constants respectively
In the above equations, the values of 'A' and 'R' can be obtained from a field survey
and the value of 'C' or 'n' can be estimated. Thus, the value of 'K' embodying all the
elements which can either be measured or estimated can be computed for any given stage.
The accuracy of 'K' depends on the errors involved in estimating the values of 'C' or 'n'
which are usually not critical. The values of 'K' covering the complete range of stages upto
the required peak level are computed and conveyance' curve is obtained by plotting 'K' as
abscissa and stage values as ordinate on rectangular co-ordinates and joining the points by a
smooth curve. A typical conveyance curve is shown in Fig 5.
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C O N V E Y A N C E (K )
X
Y
STAGE(inMetres)
●
●
●
●
● ●
●
●
●
●
●
●
●
C O N V E Y A N C E C U R V E
K = (1 /n ) . A .R .2 /3
FIGURE 5
The 'slope curve' is obtained by plotting the values of slope 'S' as abscissa and the
corresponding stage as ordinates on a rectangular co-ordinate graph paper and joining the
points thus obtained by a smooth curve. The values of slope for the purpose can be
obtained from the conveyance equation for measured values of discharge and from the
extrapolated conveyance curve for the unmeasured range of stages upto the peak stage. The
extrapolation is guided by the fact that the slope tends to become constant at higher stages
and this constant slope is the normal slope or the slope of the stream bed. If the upper end
of the defined part of the slope curve indicates that constant or near constant value of 'S' has
been attained as shown in Fig. 6, the extrapolation can be made with confidence. However,
if the upper end of the defined part of the slope curve has not reached a stage where 'S' has a
near constant value, the extrapolation is subject to uncertainty and in that situation, the
general slope of the stream bed as determined from the topographic map, should provide a
guide to the probable constant value of slope to be attained at the higher stages.
The value of discharge at any particular stage can now be obtained by
multiplying the value of 'K' from the conveyance curve and S computed from the
corresponding values of 'S' from the slope curve and thus the upper portion of the
stage-discharge relation can be constructed. It is highly unlikely that the value of 'S'
extrapolated will be with an error of ± 10% and even if an error of ± 10% is committed in
estimating 'S', the error in estimate of √ S and hence error in estimating 'Q' will be of the
order of less than 5%. The likelihood of decrease in slope at high stages, as shown by the
dotted curve to the left side of the slope curve, in Fig.6, is greatest when the over bank
flow occurs.
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X
Y
STAGE(inMetres)
SLOPE (S)
▲
▲ ▲
▲
▲
▲
▲
▲▲
▲▲
▲
EXTRAPOLATED
SLOPE CURVESLOPE CURVE
-10% +10%
FIGURE 6
This method is recommended for use because of its simplicity and also as an
accurate value of discharge with minimum error can be obtained. This method, because of
its superiority has supplanted the earlier methods, one of them being the Steven's method
i.e. Q vs A√d method.
5.2.4 Areal comparison of peak runoff rates
This method can be used to determine peak discharges at a gauging station from the
known peak discharges at the surrounding stations, when flood stages are produced over a
large area by an intense general storm. The known peak discharges are converted to peak
discharge per unit of catchment area and expressed in terms of cubic metres per second per
square kilometre. If there has been relatively little difference in storm intensity over the
area affected, the peak discharge per unit area may be correlated with the catchment area of
the gauging station under consideration. If the storm intensity is variable, the correlation
will require the use of some index of storm intensity as third variable.
This method is not recommended for use to obtain the final and accurate value of
peak discharge but could be used to obtain peak discharges which act as guide in
extrapolating the rating curve at a gauging station.
5.2.5 Flood routing
Flood routing techniques may be used to test and improve the overall consistency
of records of discharge during major floods in a river basin. The number of direct
observations of discharge during such flood periods is generally limited by the short
duration of the flood and the inaccessibility of certain stream sites. Through the use of
flood routing techniques, all observations of discharge and other hydrological events in a
river basin may be combined and used to evaluate the discharge hydrograph at a single site.
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The resulting discharge hydrograph can be then used with the stage hydrograph for that
gauge site to construct the stage-discharge relation for the site; or, if only peak stage is
available at the site, the peak stage may be used with the peak discharge computed from the
hydrograph to provide the end point for the rating curve extrapolation.
5.2.6 Step backwater method
The step backwater method is a technique in which the water surface profiles for
selected discharges are computed by successive approximations. The computations start at
a cross-section where the stage-discharge relation is defined or assumed, and proceed to the
study site, which is the hydrological station whose rating requires extrapolation. If the
flow is in the sub critical regime, as is usually the case in natural streams, the computations
must proceed in the upstream direction; and vice versa when the flow is super critical.
Under conditions of sub critical flow, the computations start at the rating defined
section and proceed upstream, subreach by subreach (in "steps"). If an initial cross section
for the computation of water surface profile is selected far enough downstream from the
study site, the computed water surface level at the study site, corresponding to any given
discharge, will have a single value regardless of the stage selected for the initial site
(Usually applicable when the initial site selected happens to be a dam or a gated structure).
After the initial site is selected, the next step is to divide the study reach i.e., the reach
between the initial site and study site, into subreaches. This is done by selecting cross
sections where major breaks in the high water profile are expected to occur because of the
changes in channel geometry of roughness. These cross sections are the end sections of
the subreaches. The cross sections are surveyed and roughness coefficients are selected for
each subreach.
The first step in the computations is to select a discharge Q at the initial section and
obtain the corresponding stage with that value of discharge. Step back water computations
are then applied to the subreach, which are based on steady flow equations viz Chezy's or
Manning's equations, after the equations are modified for non uniformity in the subreach by
use of the difference in velocity head at the end cross sections. The Chezy's equation is
related to the Manning's equation by the formula.
C = 1/n R1/6
where n is Manning's roughness coefficient and R is hydraulic radius. The
difference in water surface elevation (h) between the upstream section (subscript 1) and
downstream section (Subscript 2) is given by
(L) V1 V2 (a2 V2
2
- a1 V1
2
)(1+k)
h = h1-h2 = ------------------ + ----- ---------------------
C2
R1
1/2
R2
1/2
2g
where
h1 and h2 are the stages(at section 1 and at section 2)
L is the length of subreach
V1 and V2 are the average velocities in the crosssection (at section 1 and at sub
section 2.)
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g is the acceleration due to gravity
k is a constant
a1 and a2 are the velocity head coefficients whose value can be usually taken as 1.10
for rivers in India.
A trial value of stage for discharge Q is selected for the upstream section and the
values of A,V and R are computed for both the sections. These values are then substituted
in the above equation and after solving for 'h', the computed value of h is compared with the
difference between the trial value of the stage at upstream section and the known stage at
the downstream section. Seldom will the two values agree after a single computation and
the procedure is repeated till the values agree. After the value of the stage is computed for
the upstream section, that cross section becomes the downstream section for the next
subreach upstream. Computations similar to those described above are repeated for that
subreach, and for each subreach, till the cross section under consideration (of the study
site) is reached, to provide a water surface profile extending to the study site.
The step backwater method can be used to prepare a preliminary rating for a new
gauging station. This method can be put to best use, if computations are carried out by a
computer. Different values of stages for the downstream section are selected so that a
smooth curve can be fitted to the logarithmic plot of the discharge values at the new site.
This preliminary rating can be revised, as necessary, when subsequent discharge
measurements indicate the need for such a revision.
6.0 SHIFTS IN DISCHARGE RATINGS
Stage-discharge relations are usually subject to random fluctuations which result in
shifts of the discharge rating. These shifts indicate that the stage- discharge relations are not
permanent but vary from time to time, either gradually or abruptly, because of the changes
in physical features that form the control for the gauging station. The fluctuations in the
stage- discharge relations result from the dynamic force of moving water, and as it is
virtually impossible to sort out the minor fluctuations, a rating curve that averages the
measured discharges within close limits is considered adequate. It is also imperative that
the discharge measurements are not error free, and consequently an average curve drawn to
fit a group of measurements is probably more accurate than any single measurement.
If a group of consecutive measurements subsequently plot to the right or left of the
average rating curve, it is clearly evident that a shift in the rating curve has occurred. If,
however, only one or two measurements depart significantly from the average curve, then
these measurements could be due to a random error.
6.1 Rating shifts for natural section controls
The primary cause for changes in natural section controls is the high velocity
associated with the high discharge. While the sections with a rock ledge outcrop will be
unaffected by the high velocities, the sections with boulder, gravel and sandbar ruffles are
likely to be affected. After a flood, the ruffles are often altered so drastically as to bear no
resemblance to their pre flood state, requiring a new stage-discharge relation to be defined.
The shift curve ideally should be defined by currentmeter discharge observations. If the
shift rating is plotted on a rectangular coordinate graph it will tend to be a parallel to the
original curve, either to the left or right. The extreme low water end can be extrapolated to
the actual point of zero flow, as determined in the field when low water measurements are
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made. The shift rating on a logarithmic plot will be a curve that is either concave upward or
downward, depending on whether the shift is to the left or right.
6.2 Rating Shifts for Channel Control
In natural streams, the shifts in the section control (for low stages) are usually
accompanied by shifts in the channel control (for high stages). The most common cause of
a shift in the channel control in a relatively stable channel is scour or fill of the stream bed
caused by the high velocity flow. The scour usually occurs during a rise in the stream and
the fill on recession. This is the result of the sediment transport process, which is a very
complex process. The degree of scour in a reach is dependent not only on the magnitude of
the discharge and velocity, but also on the sediment load coming into the reach. When
scour is occurring in a pool at a meander bend, there is simultaneous filling at the crossover,
or point of inflection between successive meander bends.
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OVERHEAD SHEETS
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DISCHARGE (in Cumecs)
X
Y
STAGE(inMetres)
A STAGE DISCHARGE CURVE PLOTTEDA STAGE DISCHARGE CURVE PLOTTED
ON RECTANGULAR COORDINATESON RECTANGULAR COORDINATES
S-D CURVE
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LOG (Q)
X
Y
LOG(G-G0)
A STAGE DISCHARGE RELATIONA STAGE DISCHARGE RELATION
PLOTTED ON LOGARTHMIC SCALEPLOTTED ON LOGARTHMIC SCALE
This point of inflection
represents change in
the control
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ZERO OF GAUGE
GO
Ga
Gb
Gc
TYPICAL RIVER CROSS SECTIONTYPICAL RIVER CROSS SECTION
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CLASSIFICATION OF
STAGE DISCHARGE CONTROLS
SECTION CHANNEL
NATURAL ARTIFICIAL
PHYSICAL
PARTIAL COMPLETE COMPOUND
FUNCTIONAL
STAGE DISCHARGE CONTROLS
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IMPORTANT ATTRIBUTES
OF ARTIFICIAL CONTROLS
✔ PERMANENT AND STABLE
✔ EXCESS SEEPAGE SHOULD
BE AVOIDED
✔ D/S CONDITIONS SHOULD
NOT EFFECT CONTROL AT
HIGHER STAGES
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DISCHARGE (in Cumecs)
X
Y
STAGE(inMetres) TYPICAL S-D CURVETYPICAL S-D CURVE
Q = C(G-G0) n
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TYPICAL STAGE DISCHARGE RELATIONTYPICAL STAGE DISCHARGE RELATION
Q = C(G-G0) n
where
Q is discharge in Cumecs
G is Gauge height in Metres
G0 is gauge height for zero discharge
C is station constant and
n is the slope of the rating curve
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Q = C(G-G0) n
TAKING LOGARITHM ON BOTH SIDES
WILL YIELD
log (Q) = n log (G-G0) + log C
which is a linear equation
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LOG (Q)
X
Y
LOG(G-G0)
A STAGE DISCHARGE RELATIONA STAGE DISCHARGE RELATION
PLOTTED ON LOGARTHMIC SCALEPLOTTED ON LOGARTHMIC SCALE
log (Q) = n log (G-G0) + log C
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IN THE EQUATION SHOWN IN THE
PREVIOUS SLIDE THE UNKOWNS ARE
G0 , ‘n’ & LOG (C)
TO FIND THESE, STATISTICAL
METHODS ARE TO BE USED.
BUT BEFORE WE GO AHEAD, SOME DEFINITIONS
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DEFINITIONSDEFINITIONS
CORRELATION
REGRESSION
ASSOCIATION OF
RANDOM VARIABLES
REPRESENTS A
MATHEMATICAL
EXPRESSION
RELATING TWO OR
MORE RANDOM
VARIABLES
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HOW TO FIND G0
☛ TRIAL AND ERROR METHOD
☛ ANALYTICAL METHOD
G1.G3 - G2
2
G0 = -------------------
G1 + G3 - 2G2
☛ GRAPHICAL METHOD
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TRIAL AND ERROR METHOD
IN THIS METHOD, THE VALUES OF
‘Q’ & ‘G-G0’ ARE PLOTTED ON
LOG-LOG SHEET BY ASSUMING
CERTAIN VALUE FOR G0.
THE VALUE OF G0 IS ADJUSTED
TILL ALL THE POINTS TEND TO
FALL ALONG A STRAIGHT LINE
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0.8
0.9
1
1.1
1.2
1.3
1.4
2 3 4 5log (Q)
log(G-G0)
EXAMPLE OF
UNDERESTIMATED G0
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-2
-1.5
-1
-0.5
0
0.5
1
1.5
2 3 4 5
log (Q)
log(G-G0)
EXAMPLE OF
OVERESTIMATED G0
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0
0.2
0.4
0.6
0.8
1
1.2
1.4
2 3 4 5log (Q)
log(G-G0)
EXAMPLE OF CORRECT
ESTIMATE OF G0
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ANALYTICAL METHODANALYTICAL METHOD
Q = C(G-G0) n
SELECT THREE
VALUES OF Q1, Q2 & Q3
SUCH THAT THEY
ARE IN
GEOMETRIC SERIES,
i.e.,
Q2
2 = Q1XQ3
Q1 = C(G1-G0) n
Q2 = C(G2-G0) n
Q3 = C(G3-G0) n
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{C (G2-G0) n}2 =
i.e.,
C(G1-G0) n C(G3-G0) nX
C2 (G2-G0) 2n = C2 {(G1-G0) (G3-G0)} n
C2 (G2-G0) 2n = C2 {(G1-G0) (G3-G0)} n
(G2-G0) 2 = (G1-G0) (G3-G0)
SOLVING THE ABOVE EQUATION YIELDS
THE VALUE OF G0
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DISCHARGE (in Cumecs)
X
Y
STAGE(inMetres)
DETERMINATION OF GDETERMINATION OF GOO
BY GRAPHICAL METHODBY GRAPHICAL METHOD
Q1
Q2
Q3
A
B
C
D
E
F
GO
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HOW TO FIND ‘C’AND ‘n’
The equation log (Q) = n log (G-G0) + log C
is of the form Y = a + b X
which can be solved using ‘least squares method’
based on Legendre’s Principle.
LEGENDRE’S PRINCIPLE
“ Sum of the squares of the residuals
should be a minimum”
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DISCHARGE (in Cumecs)
X
Y
STAGE(inMetres)
G
Q
e
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ei = yi - (a + b xi)
e = observed value - computed value i.e.,
n n
E = Σ ei
2 = Σ {yi - (a + b xi)}2
i = 1 i = 1
since E is a minimum, partial differentiation
w.r.t ‘a’ and ‘b’ will be equal to zero
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i.e..,
δΕ
−−− = 0 −−−−−−−−−−−− (1)
δ a
δΕ
−−− = 0 −−−−−−−−−−−− (2)
δ b
Solving equations (1) & (2) will yield ‘a’ & ‘b’
45. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.45
DISCHARGE (in Cumecs)
X
Y
STAGE(inMetres)
DEFINED
EXAMPLE OF LOW FLOWEXAMPLE OF LOW FLOW
EXTRAPOLATIONEXTRAPOLATION
GO
EXTRAPOLATED
46. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.46
HIGH FLOWHIGH FLOW
EXTRAPOLATIONEXTRAPOLATION
✪ ?? DOUBLE LOG EXTENSION ??
✪ STEVEN’S METHOD
✪ CONVEYANCE SLOPE METHOD
✪ AREAL COMPARISON OF PEAK
RUNOFF RATES
✪ FLOOD ROUTING
✪ STEP BACKWATER METHOD
47. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.47
CONVEYANCE (K)
X
Y
STAGE(inMetres)
●
●
●●
● ●
●
●
●
●
●
●
●
CONVEYANCE CURVE
K = (1/n) . A.R.2/3
48. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.48
X
Y
STAGE(inMetres)
SLOPE (S)
▲
▲ ▲
▲
▲
▲
▲
▲▲
▲▲
▲
EXTRAPOLATED
SLOPE CURVESLOPE CURVE
49. HYDROLOGY PROJECT UNDERSTANDING STAGE -DISCHARGE RELATONS
CTU, PUNE TRAINING OF TRAINERS IN HYDROMETRY Page No.49
FROM THE CONVEYANCE CURVE,
THE VALUE OF ‘K’ CAN BE READ
FOR ANY STAGE.
SIMILARLY, FROM THE SLOPE CURVE,
THE VALUE OF SLOPE CAN BE READ
FOR ANY GIVEN STAGE.
THE VALUE OF ‘Q’ IS GIVEN BY THE
FORMULA
Q = K √ S