Method of Superposition
If n number of D-hour unit hydrographs, each one separated from the previous one by D hour, are added, one would obtain a characteristic hydrograph for n units of rainfall excess and nD-hour duration. Dividing the ordinates of this characteristic hydrograph by n would, obviously, yield a unit hydrograph (with unit rainfall excess) of duration equal to nD hours. Figure 2.23 illustrates the method of superposition which, obviously, requires n to be an integer. When n is not an integer, the summation curve (or S-curve) method is to be used.
74
IRRIGATION AND WATER RESOURCES ENGINEERING
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Sum of 4-hr unit hydrographs
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4-hr unit hydrograph
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8-hr unit hydrograph (derived)
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Fig. 2.23 Derivation of unit hydrograph of duration 2t from t-h UH
2.7.4.2. Summation Curve (or S-Curve) Method
The S-curve (or S-hydrograph) is a direct runoff hydrograph resulting from a continuous effective rainfall of uniform intensity. The S- curve is obtained by adding together a series of unit hydrographs of, say, D-hour duration each lagged by D hour in relation to the preceding one (Fig. 2.24). The intensity of effective rainfall for this S-hydrograph would, therefore, be 1/ D cm/hr. This means that each S-curve applies to a specific duration D within which one unit of direct runoff is generated. If the time base of the D-hour unit hydrograph is T hour (Fig. 2.20), then a continuous rainfall producing one unit of runoff in every period of D hours would yield a constant outflow at the end of T hours. Therefore, one needs to combine only T/ D unit hydrographs to produce an S-curve whose equilibrium flow rate Qe (in m 3/s) would be the product of area of the catchment basin and the intensity of the effective rainfall (or rainfall
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excess) i.e., 1/D cm/hr G
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=
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m / hrJ .
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100 D
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1 I
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∴
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Q = (A × 106) G
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m3/hr
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e
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H 100 DK
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= G
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× 10
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m3/hr
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(2.22)
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where, A = area of the catchment basin in km2, and
D = duration in hours of the effective rainfall of the unit hydrograph.
HYDROLOGY
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75
Rainfall excess 1/D cm/hr
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50 S-Curve
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Time in hours
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Fig. 2.24 Illustration of S-hydrograph (or S-curve)
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Alternatively,
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Qe = (A × 10 ) G
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×
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m /s
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60K
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m3/s
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...(2.23)
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e D
The S -curve ordinates sometimes oscillate at and around the equilibrium discharge. This may be due to the unit hydrograph (used for the derivation of the S-curve) which might have been derived from storms not satisfying the requirements of an ideal storm for the derivation of the unit hydrograph. An average S-curve can, however, be still drawn so as to attain the equilibrium discharge rather smoothly. The S-curve, obtained from a D-hour unit hydrograph of a catchment basin, can be used to obtain unit hydrograph (for the same catchment, of course) of another duration, say, D′ hour as explained in the following steps :
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Draw two S-curves (obtained from a D-hour unit hydrograph) with their initial points displaced on time axis by D′ hour, Fig. 2.25.
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The effective rainfall hyetographs (ERH) producing these two S-curves are also drawn in the same figure. The two ERH are also displaced by D′ hour. The difference between these two effective rainfall hyetographs represents a storm of duration D′ with an intensity of 1/D cm/hr and, hence, a rainfall of magnitude D′/D cm.
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The difference between the ordinates of the two S-curves at any time [i.e. S(t)-S (t – D′)] gives the ordinate of a direct runoff hydrograph at that time, Fig. 2.25. This hydrograph is, obviously, for the storm of duration D′ with an intensity of 1/D cm/hr having rainfall excess of
D′/D cm which is the runoff volume.
76 IRRIGATION AND WATER RESOURCES ENGINEERING
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Excess rainfall at
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cm/hr
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D
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D¢
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Discharge
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S-Curve
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Lagged s-curve
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S( t )
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S( t – D¢ )
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D¢
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Discharge
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Difference graph
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[S( t ) – S( t – D¢ )]
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Time in hours
Fig. 2.25 Derivation of D′ hour UH by S-curve method
4. Compute the ordinates of the D′-hour unit hydrograph by multiplying the S-curve differences [i.e., S(t) – S(t – D′)] with the ratio D/D′.
Earlier, it has been stated that one requires combining T/D unit hydrographs suitably for obtaining a S -curve. However, one can construct S-curve without requiring to tabulate and adding T/D unit hydrographs with successive time lags of D hours. The difference of two-S-curves (derived from a D-hour unit hydrograph) lagged by D hour itself is nothing but the D-hour unit hydrograph itself. Therefore, the ordinate U(t) of a D-hour unit hydrograph at any time t is given as
U(t) = S(t) – S (t – D)
or S(t) = U(t) + S(t – D) (2.24)
The term S (t – D) is called the S-curve addition which is an ordinate of S-curve itself but at time (t – D). It may be noted that for t ≤ D.
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And for t > D, one has to use Eq. (2.24) for constructing S-curve.
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