HYDROLOGY II
CHAPTER 2 (2) - ROBERSON ET AL, WITH ADDITIONS
f = fc + (fo - fc ) e-kt
SCS (NRCS) PRACTICE
|
- IN LIEU OF HORTON'S INFILTRATION, AN AVERAGE INFILTRATION CAPACITY φ-INDEX
HAS BEEN USED BECAUSE OF ITS SIMPLICITY.
|
- DURING FLOODS, A φ-INDEX IS A GOOD REPRESENTATION.
- EVAPORATION FROM WATER (Ew) AND SOIL
SURFACES (En) AND TRANSPIRATION THROUGH
PLANTS (T) CAN ACCOUNT FOR SIGNIFICANT
VOLUMES OF WATER.
- EVAPORATION IS THE PROCESS BY WHICH
WATER TRANSFORMS INTO VAPOR.
- EVAPORATION FROM A WATER BODY IS A
FUNCTION OF AIR AND WATER TEMPERATURES,
THE MOISTURE GRADIENT AT THE WATER
SURFACE, AND THE WIND SPEED.
- DALTON FORMULA (GENERIC):
- E = (es - ea) f(u)
- es = saturation vapor pressure at the water surface
temperature
- ea = vapor pressure of the overlying air
- eo = saturation vapor pressure at the air
temperature
- ea = eo (RH%) /100
- f(u) = wind function
- MEYER EQUATION:
- E = C (eo - ea) [ 1 + (W/10)]
E = EVAPORATION, IN IN/MONTH
- C = COEFFICIENT VARYING FROM 11 (LAKES AND
RESERVOIRS) TO 15 (SMALL PONDS) .
- eo = SATURATION VAPOR PRESSURE OF THE AIR AT THE MEAN MONTHLY AIR TEMPERATURE,
IN INCHES OF MERCURY.
- W = MEAN MONTHLY WIND SPEED AT 25-FT
HEIGHT, IN MILES/HR.
- EVAPORATION RATES VARY FROM AS MUCH AS
86 IN PER YEAR IN SOUTHEAST CALIFORNIA TO
20 IN PER YEAR IN NORTHERN MAINE.
- THE STANDARD CLASS A PAN IS USED TO MEASURE EVAPORATION.
EVAPORATION AND EVAPOTRANSPIRATION
|
- EVAPOTRANSPIRATION IS THE TOTAL MOISTURE
THAT LEAVES THE AREA.
- IT CONSISTS OF EVAPORATION AND EVAPOTRANSPIRATION.
- THERE IS EVAPORATION FROM WATER BODIES.
- THERE IS EVAPOTRANSPIRATION FROM ECOSYSTEMS, INCLUDING LAND AND WATER.
- CONVENTIONAL WISDOM STATES THAT IN TEMPERATE REGIONS, EVAPORATION AND EVAPOTRANSPIRATION ARE ROUGHLY THE SAME.
- PENMAN SUGGESTED THAT EVAPOTRANSPIRATION IS 60% OF EVAPORATION IN THE WINTER, AND 80% DURING THE SUMMER.
- ONLINE CALCULATION OF EVAPORATION/EVAPOTRANSPIRATION: ONLINEHYDRO.
- TIME OF CONCENTRATION:
- THE TIME REQUIRED FROM A DROP OF WATER
TO TRAVEL ON THE LAND SURFACE,
FROM THE MOST DISTANT POINT IN THE
WATERSHED/BASIN TO THE OUTLET.
- THE CONTINUOUS RECORD OF FLOW AT A
STATION IS CALLED STREAM HYDROGRAPH.
- THE SHAPE OF THE HYDROGRAPH REFLECTS
PHYSICAL CHARACTERISTICS OF THE DRAINAGE
BASIN, AS WELL AS THAT OF THE STORM
PRODUCING THE HYDROGRAPH.
- PEAKED HYDROGRAPHS SHOW LITTLE
DIFFUSION: SMALL MOUNTAINOUS
BASINS.
- SMOOTH HYDROGRAPHS SHOW GREAT
DIFFUSION: LARGE BASINS OF MILD
OVERALL SLOPE.
- STEEP SLOPES WILL PRODUCE MORE RUNOFF
THAT FLAT SLOPES?
- VEGETATED DRAINAGE AREAS WILL PRODUCE
LESS RUNOFF THAN BARE AREAS?
RAINFALL-RUNOFF RELATIONS
|
Tesechoacan river at Azueta, Mexico, year 1972.
- QUANTITY OF RUNOFF DEPENDS ON WHETHER IT
IS SHORT TERM OR LONG-TERM.
- WHETHER THE RUNOFF COMES FROM SURFACE S OR
SUBSURFACE U.
- WE HAVE TO DISTINGUISH BETWEEN PEAK AND
VOLUME.
- PEAK IS SHORT-TERM; VOLUME IS LONG-TERM.
- THE SAME CHARACTERISTICS THAT WILL
DECREASE SHORT-TERM RESPONSE WILL
INCREASE LONG-TERM RESPONSE.
- RATIONAL EQUATION IS THE CLASSICAL
SHORT-TERM RESPONSE MODEL.
- IT FOCUSES ONLY ON THE PEAK DISCHARGE.
- THE VOLUME CAN ALSO BE CALCULATED, BUT IT
IS NOT THE MAIN FOCUS.
- Qp = CIA
- THIS EQUATION HAS BEEN WIDELY USED IN THE
DESIGN OF SMALL DRAINAGE SYSTEMS, SUCH
AS AIRPORT AND URBAN DRAINAGE.
- THE RUNOFF COEFFICIENT VARIES FROM 0 TO 1;
IN PRACTICE, RANGE OF 0.05-0.95.
- RATIONAL EQUATION IS DIMENSIONALLY
HOMOGENEOUS.
- IT IS RATIONAL BECAUSE IT IS BASED ON THE
RUNOFF CONCENTRATION PRINCIPLE.
- IT JUST SAYS THAT PEAK DISCHARGE WILL BE A
PERCENTAGE OF THE MAXIMUM POSSIBLE, WITH
THE PERCENTAGE DETERMINED EMPIRICALLY.
- THE MAXIMUM POSSIBLE DISCHARGE IS
RATIONAL.
- RAINFALL DURATION IS EQUAL TO THE TIME OF CONCENTRATION.
- KIRPICH FORMULA:
tc = (0.0000335L3/h) 0.385
- tc = time of concentration, minutes
- L = stream length, feet
- h = maximum difference in elevation in drainage
basin, feet
- HATHAWAY FORMULA:
tc = {2Ln / [3(S)0.5]} 0.47
- tc = time of concentration, minutes
- L = stream length, feet
- S = mean slope of the basin
- n = Manning's roughness coefficient.
- SIMPLICITY OF THE RATIONAL METHOD IS MISLEADING.
- THE RUNOFF COEFFICIENT FOUND IN TABLES IS
FOR 5 AND 10 YR FREQUENCY.
- FOR LONGER FREQUENCIES, GREATER VALUES
ARE JUSTIFIED.
- FREQUENCY OF RAINFALL EQUAL TO
FREQUENCY OF RUNOFF?
EXAMPLE 2-11
USE THE RATIONAL METHOD TO FIND THE 10-YR PEAK RATE OF RUNOFF FOR THE TWO AREAS, AND FOR THE CHANNEL AT POINT b.
|
- ALL FLOW FROM AREA A1 ENTERS THE CHANNEL AT POINT a.
- ALL FLOW FROM AREA A2 ENTERS THE CHANNEL AT POINT b.
- ASSUME IDF OF FIG 2-16 IS APPLICABLE.
- TIME OF FLOW FROM a TO b IS 8 MINUTES.
- SOLUTION:
- FOR A DURATION OF 20 MINUTES, FIG. 2-16
SHOWS I = 1.2 IN/HR
|
- THE PEAK RATE OF FLOW AT a IS:
- Qp = CIA = 0.6 × 1.2 × 6 = 4.3 CFS.
- THE PEAK RATE OF FLOW AT b, WITHOUT AREA
A1, IS:
- Qp = CIA = 0.8 × 2.3 × 4 = 7.4 CFS.
- TO FIND THE PEAK RATE OF FLOW AT b, WE
MUST CONSIDER BOTH AREAS SIMULTANEOUSLY.
- THE TIME OF CONCENTRATION AT b IS
20 + 8 = 28 min.
- THE PEAK RATE OF FLOW AT b, WITH AREA A1,
IS:
- Qp = ∑ CIA = (0.6 × 1.0 × 6) + (0.8 × 1.0 × 4) =
6.8 CFS.
- THIS ASSUMES ONLY ONE STORM. NEGLECTS
TRANSPORT IN THE CHANNEL.
- STORAGE IN CHANNEL IS NEGLECTED BY
RATIONAL METHOD.
- BOOK ASSUMES TWO STORMS, AND INCLUDES
TRANSPORT IN THE CHANNEL.
IN THIS CASE:
- Qp = ∑ CIA = (0.6 × 1.2 × 6) + (0.8 × 1.0 × 4) =
7.5 CFS.
- SEE HOW DIFFERENT ASSUMPTIONS ABOUT
STORMS CAN MAKE THE ANALYSIS COMPLEX.
- CURVE NUMBER METHOD:
- USED WHERE RUNOFF RECORDS ARE NOT
AVAILABLE.
- RUNOFF CAN BE DETERMINED IN TERMS OF A
SINGLE PARAMETER CN.
- CN VALUES WERE DEVELOPED EMPIRICALLY
BASED ON DATA ON RAINFALL, SOIL TYPES,
COVER, LAND USE, SOIL CONDITION, AND ANTECEDENT MOISTURE.
- CN SHOWN IN TABLES ARE FOR AMC II [NORMAL MOISTURE], WHICH
HAS BEEN FOUND TO FREQUENTLY PRECEDE THE OCCURRENCE OF ANNUAL FLOODS.
- DEVELOPMENT OF CURVE NUMBER METHOD IS
CONCEPTUAL/EMPIRICAL.
- THE MAIN CONCEPT OF CN METHOD IS THAT
RETENTION ACHIEVES A MAXIMUM VALUE,
KNOWN AS POTENTIAL RETENTION.
- INFILTRATION RATE ULTIMATELY BECOMES
ZERO.
- THIS ASSUMPTION IS GOOD FOR FLOODS,
BECAUSE SOIL PROFILES CAN BE COMPLETELY FILLED;
THEY ARE NOT INFINITELY LEAKING.
- RUNOFF CURVE NUMBER EQUATION:
PROPORTIONALITY BETWEEN RETENTION AND
RUNOFF:
(P - Q) / S = Q /P
- THE RATIO OF ACTUAL RETENTION (P - Q) TO
POTENTIAL RETENTION S, IS EQUAL TO THE
RATIO OF ACTUAL RUNOFF Q TO POTENTIAL
RUNOFF P.
- IN PRACTICE, AN INITIAL ABSTRACTION IS
INCLUDED BECAUSE EXPERIENCE SHOWS
THAT RUNOFF DOES NOT BEGIN IMMEDIATELY
AFTER RAINFALL BEGINS.
- (P - Ia - Q) / S = Q /(P - Ia)
- Ia = 0.2 S
- Q = (P - 0.2 S)2 /(P + 0.8 S)
- SINCE S VARIES WITHIN A RELATIVELY LARGE
RANGE (ZERO TO INFINITY), A MAPPING PARAMETER CN IS INTRODUCED, SUCH THAT
- CN = 100
FOR S = 0; AND CN = 1 FOR S = 990 IN.
- NOTE THAT THE TRANSFORMATION IS ARBITRARY.
- CN IS A SURROGATE FOR S.
- TABLE CN IS FOR AMCII.
- DRIER CONDITIONS (AMC I) WILL PRODUCE LESS
RUNOFF; WETTER CONDITIONS (AMC III ) WILL PRODUCE
MORE RUNOFF.
SOIL-COVER COMPLEX METHOD
|
- PROCEDURE FOR USING CN METHOD
- EXAMPLE 2-12:
- DETERMINE 2-HR INCREMENTS
OF RUNOFF FOR THE 100-YR, 24-HR STORM OF
TABLE 2-6 FOR A 100-ACRE DRAINAGE AREA IN
GOOD HYDROLOGIC CONDITION, WITH THE
FOLLOWING CHARACTERISTICS:
25 ACRES IS COMPOSED OF PASTURELAND HAVING A SHALLOW SANDY-LOAM SOIL, AND 75 ACRES IS FOREST LAND WITH A CLAY LOAM SOIL.
ASSUME CONSIDERABLE RAIN HAS PRECEDED THE STORM TO BE ANALYZED.
- SOLUTION:
- 25-ACRE SUBAREA: SOIL GROUP C, CN = 74
(PASTURE)
- 75-ACRE SUBAREA: SOIL GROUP C, CN = 70
(WOODS)
- CN (AVERAGE) = [(74 X 25) + (70 X 75)]/100 = 71
- ASSUME WET CONDITION. FROM TABLE 72:
CN = 88
- DEVELOP TABLE OF ACCUMULATED PRECIPITATION IN TWO-HOUR INCREMENTS.
- FOR EACH PRECIPITATION, FIND Q FOR CN= 88.
- THE TOTAL RUNOFF IS 6.1 IN, THE TOTAL PRECIPITATION IS 7.5 IN.
- 1.4 IN WERE LOST TO INFILTRATION.
- METHOD QUESTIONABLE FOR AREAS GREATER
THAN 5 TO 10 SQUARE MILES?
- TR-55 METHOD.
- MORE ON THE SCS METHOD.
-- STUDY THE SOIL TYPE, LAND USE AND COVER, HYDROLOGIC CONDITION, AND AMC OF DRAIN AGE AREA. SELECT A PROPER HYDROLOGIC SOIL GROUP. MAY NEED AERIAL WEIGHING.
-- SELECT CN FOR PROPER HYDROLOGIC CONDITION: POOR, FAIR, GOOD.
-- SPATIALLY WEIGH CN VALUES.
-- FIND ACCUMULATED PRECIPITATION, IN.
-- ESTIMATE RUNOFF USING P AND CN.
|
Deforestation in Loja, Ecuador.
- DETERMINATION OF PEAK STREAMFLOW THAT
WILL BE EQUALED OR EXCEEDED ON THE
AVERAGE ONCE IN A SPECIFIED NUMBER
OF YEARS.
- PEAK FLOW CAN BE DETERMINED THROUGH
STATISTICAL MEANS.
- WHEN Q RECORDS ARE NOT AVAILABLE, BUT P
RECORDS ARE AVAILABLE, USE UNIT HYDROGRAPH FOR MIDSIZE BASINS.
- THE HYDROGRAPH:
- IT IS DIVIDED INTO
-- BASEFLOW,
-- RISING LIMB,
-- PEAK SEGMENT,
-- FALLING LIMB.
STREAMFLOW
|
- RECESSION CURVE IS DUE TO FLOW OF
GROUNDWATER.
- TIME-TO-PEAK IS IMPORTANT.
- BANK STORAGE IS ALSO IMPORTANT.
- STREAMFLOW HYDROGRAPH INTEGRATES ALL
THE PHYSICAL PROPERTIES OF THE BASIN.
- UNIT HYDROGRAPH: HYDROGRAPH FOR 1 UNIT OF
EFFECTIVE RAIN FOR A GIVEN DURATION AND
DRAINAGE AREA.
UNIT HYDROGRAPH
BUILDING BLOCK TO BUILD THE STORM OR FLOOD HYDROGRAPH.
|
- LINEARITY AND SUPERPOSITION ARE THE
PRINCIPLES OF THE UNIT GRAPH.
- TWO TYPES OF UNIT HYDROGRAPHS:
-- MEASURED
-- SYNTHETIC
- SYNTHETIC UNIT HYDROGRAPHS WHEN DATA IS NOT AVAILABLE.
- SNYDER AND SCS METHODS.
- THEY ARE BASED ON TIME LAG (TIME TO PEAK), PEAK
FLOW FORMULA, AND TIME BASE FORMULA.
- SNYDER METHOD PROVIDES A REASONABLE ESTIMATE FOR LARGE BASINS (MORE THAN 400 MI2) .
- SCS METHOD IS MORE APPROPRIATE FOR SMALLER BASINS (LESS THAN 400 MI2).
- FOR SMALL WATERSHEDS, THE TIME BASE IS
APPROXIMATELY 4-5 TIMES THE TIME TO PEAK.
- STORM DURATION SHOULD NOT EXCEED 20 PERCENT OF THE TIME OF CONCENTRATION.
- CONVOLUTION: COMPOSITE FLOOD HYDROGRAPHS.
| 071214 |