Hydrologic Routing

Reading: Applied Hydrology Sections 8.1, 8.2, 8.4

2

Flow Routing

• Procedure to determine the flow hydrograph at a point on a watershed from a known hydrograph upstream

• As the hydrograph travels, it– attenuates – gets delayed

Q

t

Q

t

Q

t

Q

t

3

Why route flows?

Account for changes in flow hydrograph as a flood wave passes downstream

This helps in Accounting for storages Studying the attenuation of flood peaks

Q

t

4

Types of flow routing

• Lumped/hydrologic– Flow is calculated as a function of time alone at a

particular location– Governed by continuity equation and

flow/storage relationship • Distributed/hydraulic

– Flow is calculated as a function of space and time throughout the system

– Governed by continuity and momentum equations

5

Hydrologic Routing

Inflow)( tI Outflow)( tQUpstream hydrograph Downstream hydrograph

)()( tQtIdt

dS

Input, output, and storage are related by continuity equation:

Discharge

Inflow)(tI Discharge

Outflow

)(tQTransferFunction

Q and S are unknown

Storage can be expressed as a function of I(t) or Q(t) or both

),,,,,( dt

dQQ

dt

dIIfS

For a linear reservoir, S=kQ

6

Lumped flow routing

• Three types1. Level pool method (Modified Puls)

– Storage is nonlinear function of Q

2. Muskingum method– Storage is linear function of I and Q

3. Series of reservoir models– Storage is linear function of Q and its time

derivatives

7

S and Q relationships

8

Level pool routing

• Procedure for calculating outflow hydrograph Q(t) from a reservoir with horizontal water surface, given its inflow hydrograph I(t) and storage-outflow relationship

9

Level pool methodology

1jI

Discharge

Time

Storage

Time

jI

1jQ

jQ

1jS

jS

tj )1(tj

t

Inflow

Outflow

)()( tQtIdt

dS

tj

tj

tj

tj

jS

jS

QdtIdtdS)1()1(1

22111 jjjjjj QQII

t

SS

jj

jjjj

Qt

SIIQ

t

S

22

111

Unknown KnownNeed a function relating

QQt

Sand,

2 Storage-outflow function

10

Level pool methodology• Given

– Inflow hydrograph– Q and H relationship

• Steps1. Develop Q versus Q+ 2S/Dt relationship using

Q/H relationship2. Compute Q+ 2S/Dt using 3. Use the relationship developed in step 1 to get Q

jj

jjjj

Qt

SIIQ

t

S

22

111

11

Ex. 8.2.1

Given I(t)Time Inflow(min) (cfs)

0 010 6020 12030 18040 24050 30060 36070 32080 28090 240

100 200110 160120 120130 80140 40150 0160 0170 0180 0190 0200 0210 0

Given Q/HElevation H Discharge Q

(ft) (cfs)0 0

0.5 31 8

1.5 172 30

2.5 433 60

3.5 784 97

4.5 1175 137

5.5 1566 173

6.5 1907 205

7.5 2188 231

8.5 2429 253

9.5 26410 275

0

100

200

300

400

0 50 100 150 200 250

Time (min)

Infl

ow

(cf

s)

Area of the reservoir = 1 acre, and outlet diameter = 5ft

12

Ex. 8.2.1 Step 1Develop Q versus Q+ 2S/Dt relationship using Q/H relationship

Elevation H Discharge Q Storage S 2S/ t + Q

(ft) (cfs) (ft3) (cfs)0 0 0 0

0.5 3 21780 75.61 8 43560 153.2

1.5 17 65340 234.82 30 87120 320.4

2.5 43 108900 4063 60 130680 495.6

3.5 78 152460 586.24 97 174240 677.8

4.5 117 196020 770.45 137 217800 863

5.5 156 239580 954.66 173 261360 1044.2

6.5 190 283140 1133.87 205 304920 1221.4

7.5 218 326700 13078 231 348480 1392.6

8.5 242 370260 1476.29 253 392040 1559.8

9.5 264 413820 1643.410 275 435600 1727

3780,215.043560 ftHeightAreaS

cfsQt

S6.753

6010

2178022

0

50

100

150

200

250

300

0 500 1000 1500 2000

2S/ t + Q (cfs)

Ou

tflo

w Q

(cf

s)

13

Step 2

Compute Q+ 2S/Dt using jj

jjjj

Qt

SIIQ

t

S

22

111

At time interval =1 (j=1), I1 = 0, and therefore Q1 = 0 as the reservoir is empty

11

1222 22

Qt

SIIQ

t

S

Write the continuity equation for the first time step, which can be used to compute Q2

6060022

11

1222

Q

t

SIIQ

t

S

14

Step 3Use the relationship between 2S/Dt + Q versus Q to compute Q

602

22

Q

t

S

Elevation H Discharge Q Storage S 2S/ t + Q

(ft) (cfs) (ft3) (cfs)0 0 0 0

0.5 3 21780 75.61 8 43560 153.2

1.5 17 65340 234.82 30 87120 320.4

2.5 43 108900 4063 60 130680 495.6

3.5 78 152460 586.24 97 174240 677.8

4.5 117 196020 770.45 137 217800 863

5.5 156 239580 954.66 173 261360 1044.2

6.5 190 283140 1133.87 205 304920 1221.4

7.5 218 326700 13078 231 348480 1392.6

8.5 242 370260 1476.29 253 392040 1559.8

9.5 264 413820 1643.410 275 435600 1727

Use the Table/graph created in Step 1 to compute Q

What is the value of Q if 2S/Dt + Q = 60 ?

cfsQ 4.2)060()076(

)03(0

So Q2 is 2.4 cfs

Repeat steps 2 and 3 for j=2, 3, 4… to compute Q3, Q4, Q5…..

0

50

100

150

200

250

300

0 500 1000 1500 2000

2S/ t + Q (cfs)

Ou

tflo

w Q

(cf

s)

15

Ex. 8.2.1 resultsj

jjjj

jQ

t

SIIQ

t

S

22

111

jjj

jj QQ

t

SQ

t

S2

22

16

Ex. 8.2.1 results

0

50

100

150

200

250

300

350

400

0 20 40 60 80 100 120 140 160 180 200 220

TIme (minutes)

Dis

ch

arg

e (

cfs

)

Inflow

Outflow

Peak outflow intersects with the receding limb of the inflow hydrograph

0.0

2.0

4.0

6.0

8.0

10.0

12.0

0 20 40 60 80 100 120 140 160 180 200 220

Time (minutes)

Sto

rag

e (a

cre-

ft)

Outflow hydrograph

17

Q/H relationships

http://www.wsi.nrcs.usda.gov/products/W2Q/H&H/Tools_Models/Sites.html Program for Routing Flow through an NRCS Reservoir

Hydrologic river routing (Muskingum Method)

Wedge storage in reach

IQ

QQ

QI

AdvancingFloodWaveI > Q

II

IQ

I Q

RecedingFloodWaveQ > I

KQS Prism

)(Wedge QIKXS

K = travel time of peak through the reachX = weight on inflow versus outflow (0 ≤ X ≤ 0.5)X = 0 Reservoir, storage depends on outflow, no wedgeX = 0.0 - 0.3 Natural stream

)( QIKXKQS

])1([ QXXIKS

19

Muskingum Method (Cont.)])1([ QXXIKS

]})1([])1({[ 111 jjjjjj QXXIQXXIKSS

tQQ

tII

SSjjjj

jj

22

111

jjjj QCICICQ 32111

tXK

tXKC

tXK

KXtC

tXK

KXtC

)1(2

)1(2

)1(2

2

)1(2

2

3

2

1

Recall:

Combine:

If I(t), K and X are known, Q(t) can be calculated using above equations

20

Muskingum - Example• Given:

– Inflow hydrograph– K = 2.3 hr, X = 0.15, Dt = 1 hour,

Initial Q = 85 cfs• Find:

– Outflow hydrograph using Muskingum routing method

Period Inflow (hr) (cfs)

1 93 2 137 3 208 4 320 5 442 6 546 7 630 8 678 9 691

10 675 11 634 12 571 13 477 14 390 15 329 16 247 17 184 18 134 19 108 20 90

5927.01)15.01(3.2*2

1)15.01(*3.2*2

)1(2

)1(2

3442.01)15.01(3.2*2

15.0*3.2*21

)1(2

2

0631.01)15.01(3.2*2

15.0*3.2*21

)1(2

2

3

2

1

tXK

tXKC

tXK

KXtC

tXK

KXtC

21

Muskingum – Example (Cont.)

jjjj QCICICQ 32111 Period Inflow C1Ij+1 C2Ij C3Qj Outflow

(hr) (cfs) (cfs) 1 93 0 0 0 85 2 137 9 32 50 91 3 208 13 47 54 114 4 320 20 72 68 159 5 442 28 110 95 233 6 546 34 152 138 324 7 630 40 188 192 420 8 678 43 217 249 509 9 691 44 233 301 578

10 675 43 238 343 623 11 634 40 232 369 642 12 571 36 218 380 635 13 477 30 197 376 603 14 390 25 164 357 546 15 329 21 134 324 479 16 247 16 113 284 413 17 184 12 85 245 341 18 134 8 63 202 274 19 108 7 46 162 215 20 90 6 37 128 170

0

100

200

300

400

500

600

700

800

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20

Time (hr)

Dis

cha

rge

(cfs

)

C1 = 0.0631, C2 = 0.3442, C3 = 0.5927