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Time of Concentration and Lag Time in WMS

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Title: Time of Concentration and Lag Time in WMS


1
Time of Concentration and Lag Time in WMS
  • Ryan Murdock
  • CE 394K.2

2
Travel Time Basic Concepts
  • Time of concentration
  • Longest time of travel for a drop of water to
    reach the watershed outlet (as used in rational
    method)
  • Time from the end of rainfall excess to the
    inflection point on the hydrograph recession
    curve (as considered in SCS method)
  • Lag time
  • Time from the center of mass of rainfall excess
    to hydrograph peak

3
Hydrograph Properties
Taken from Wanielista, M., R. Kersten, and R.
Eaglin, Hydrology Water Quantity and Quality
Control, p. 184
4
WMS Travel Time Methods
  • Empirical equations based on basin data
  • Create a time computation coverage
  • Define representative flow path(s) within each
    basin using arcs
  • Travel time equation assigned to each arc

5
WMS Examples
6
WMS Models Requiring Travel Time Input
  • TR-55 (tc)
  • TR-20 (tlag)
  • HEC-1 (depends on unit hydrograph method)
  • Rational Method (tc)

7
Computing Travel Times From Map Data- TR-55
Equations
  • Sheet Flow
  • Tt (hr) 0.007(nL(ft))0.8/(P20.5S0.4)
  • P2 2 yr , 24 hr rainfall (TR-55 manual, NOAA)
  • Equation used for lengths lt300 ft
  • Shallow Concentrated Flow
  • Tt (hr) L(ft)/3600V(fps)
  • V determined from slope of flow path
  • Open Channel Flow (Mannings equation)
  • TtL/VLn/(1.49R0.67S 0.5)
  • R obtained from WMS channel calculator
  • tcSTt
  • Other Equations - FHWA and Maricopa Co., AZ

8
Rational Method
9
Rational Method Hydrograph
QpCiA
Taken from Wanielista, M., R. Kersten, and R.
Eaglin, Hydrology Water Quantity and Quality
Control, p. 208
10
Time of Concentration
11
Time of Concentration Methods (1)
  • Kirpich Equation (1940)
  • For overland flow
  • tc (hrs) m0.00013(L0.77/S0.385)
  • L length of overland flow (ft)
  • S avg overland slope
  • m based on earth type
  • bare earth1, grassy earth2, concrete
    asphalt0.4
  • In mountains multiply computed tc by
    (1(80-CN)0.4)
  • Based on data from small agricultural watersheds
  • Steep slopes
  • Well-drained soils
  • Timber cover 0- 56
  • Area 1.2- 112 acres

12
Time of Concentration Methods (2)
  • Ramser Equation (1927)
  • For well-defined channels
  • tc (min) m0.0078(Lc0.77/Sc0.385)
  • m 0.2 for concrete channels
  • Lc length of channel reach (ft)
  • Sc avg channel slope
  • Kerby Equation (1959)
  • For overland flow distances 300 - 500 ft
  • tc (min) (0.67nLo)/S0.50.467
  • Lo length of overland flow (ft)
  • n Mannings roughness coefficient
  • S avg overland slope

13
Time of Concentration Methods (3)
  • Fort Bend County, Texas (1987)
  • For use with Clark unit hydrograph method
  • tc (hrs)48.64(L/S0.5)0.57logSo/(So0.1110I)
  • L length of longest flow path (mi)
  • S avg slope along longest flow path
  • So avg basin slope
  • I impervious area
  • Applicable watershed conditions
  • Area 0.13- 400 mi2
  • Longest flow path 0.5- 55 mi
  • Slope of longest flow path 2- 33 ft/mi
  • Basin slope 3- 80 ft/mi

14
HEC-1 Unit Hydrographs
15
SCS Hydrograph
qp484AQ/(0.5D0.6tc)
Taken from Handbook of Hydrology, p. 9.25
16
Lag Time
17
Lag Time Methods
  • General form of equation
  • TLAG Ct(LLca/S0.5)m
  • Ct coefficient accounting for differences in
    watershed slope and storage
  • L max flow length along main channel from point
    of reference to upstream watershed boundary (mi)
  • Lca distance along main channel from point of
    reference to a point opposite the centroid (mi)
  • S slope of the maximum flow distance path
    (ft/mi)
  • m lag exponent
  • WMS allows user to customize the parameters
  • (enter your own Ct m)

18
Lag Time Methods- General Form (1)
  • Denver Area Flood Control District (1975)
  • m0.48, Ct based on impervious
  • For small urban watersheds (lt5 mi2) with mild
    slopes
  • Tulsa District USACoE
  • For use with Snyder unit hydrograph
  • Parameters
  • Ct 1.42 (natural watersheds in rural areas of
    central NE Oklahoma), 0.92 (50 urbanized),
    0.59 (100 urbanized)
  • L watershed max flow distance (mi)
  • S slope of max flow dist (ft/mi)
  • Applicable conditions
  • Area 0.5- 500 mi2
  • Slope 4- 90 ft/mi
  • Length 1- 80 mi
  • Length to centroid 1- 60 mi

19
Lag Time Methods- General Form (2)
  • Riverside County Flood Control WCD (1963)
  • Ct 1.2 mountainous, 0.72 foothills, 0.38 valleys
  • m 0.38
  • Areas near Riverside Co., CA (2- 650 mi2)
  • Eagleson (1962)
  • Completely storm-sewered watersheds
  • Ct 0.32, m 0.39
  • Typical Characteristics
  • Area 0.22- 7.5 mi2, L 1-7 mi, Lca 0.3-3 mi, S
    6-20 ft/mi,
  • 33-83 impervious
  • Taylor Schwartz (1952)
  • For Snyder unit hydrograph
  • Developed in northeastern region of US
  • Ct 0.6, m0.3

20
Lag Time- Adaptations to General Form
  • Putnam (1972)
  • TLAG 0.49(L/S0.5)0.5Ia-0.57
  • Watersheds around Wichita, Kansas
  • Typical conditions
  • Area 0.3-150 mi2, Ia lt0.3, 1 lt (L/S0.5) lt9
  • Colorado State University
  • TLAG Ct(LLca)0.3
  • Ct 7.81/Ia0.78
  • For watersheds in Denver, CO area
  • With some amount of developed land
  • Not valid when Ialt10

21
Lag Time- SCS method
  • SCS (1972)
  • TLAG L0.8(S1)0.7/(1900Y0.5)
  • L hydraulic lengthof watershed (ft)
  • S(1000/CN)-10 max retention (in)
  • Y watershed slope ()
  • TLAG 0.6 tc

22
Time to Rise
  • Espey (1966)
  • For Snyders time to rise (time from beginning of
    effective rainfall to hydrograph peak)
  • Developed for small watersheds in TX, OK, NM
  • Rural areas Tr 2.65Lf 0.12Sf-0.52
  • Lf stream length (ft)
  • Sf stream slope
  • Typical Conditions
  • Lf 3250-25300 ft, Sf 0.008-0.015, Tr 30-150
    min, Area 0.1-7 mi2
  • Urban Areas Tr 20.8 ULf0.29Sf-0.11Ia-0.61
  • Ia percent impervious cover
  • U urbanization factor (0.6 extensive- 1 natural
    conditions)
  • Typical Conditions
  • Lf 200-54,800 ft, Sf 0.0064-0.104, Ia 25-40,
    Tr 30-720 min, Area 0.0125-92 mi2
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