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HomeMy WebLinkAboutLot 1-4 Hydrology and Hydraulics ReportHYDROLOGY AND HYDRAULICS REPORT FOR VAIL RANCH - VILLAGE 3 TRACT 28832 IN THE COUNTY OF RIVERSIDE Prepared for: PRESLEY HOMES 15373 Innovation Drive, Suite 380 San Diego, California 92128 (619)451-6300 Prepared by: SB&O, INC. 9007 Arrow Route, #120 Rancho Cucamonga, California 91730 (909) 948-3450 U DONALD R. BROOKS, PE 41829 February 15, 1999 xtY., Nearest computed pipe diameter = 9.00(Iii.) Calculated individual pipe flow = 5.120(CFS) Normal flow depth in pipe = 5.60(In.) Flow top width inside pipe = 8.73(In.) Critical depth could not be calculated. Pipe flow velocity = 17.73(Ft/s) Travel time through pipe = 0.02 min. Time of concentration (TC) = 12.85 min. ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 12.000 to Point/Station 13.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 3 Stream flow area = 1.940(Ac.) Runoff from this stream = 5.120(CFS) Time of concentration = 12.85 min. Rainfall intensity = 3.035(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (min) (In/Hr) 1 21.667 17.71 2.544 2 13.254 11.86 3.171 3 5.120 12.85 3.035 Largest stream flow has longer time of concentration Qp = 21.667 + sum of Qb Ia/Ib 13.254 * 0.802 = 10.633 Qb Ia/Ib 5.120 * 0.838 = 4.292 Qp = 36.592 Total of 3 streams to confluence: Flow rates before confluence point: 21.667 13.254 5.120 Area of streams before confluence: 9.120 4.800 1.940 Results of confluence: Total flow rate = 36.592(CFS) Time of concentration = 17.705 min. Effective stream area after confluence = 15.860(Ac.) Process from Point/Station 13.000 to Point/Station. 16.000 .41 Pipe length = 650.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 36.592(CFS) Nearest computed pipe diameter = 36.00(In.) Calculated individual pipe flow = 36.592(CFS) Normal flow depth in pipe = 25.92(In.) ilY's, Flow top width inside pipe= 32.33(In.) Critical Depth= 23.60(In.) 3,t. Pipe flow velocity = 6.72(Ft/s) Travel time through pipe = 1.61 min. Time of concentration (TC) = 19.32 min. . s. ++++++++++ TAT+++++++++++++++++.H H .++++++++++++++ Process from Point/Station 13.000 to Point/Station 16.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number Stream flow area = 15.860(Ac.) Runoff from this stream = 36.592(CFS) Time of concentration = 19.32 min. Rainfall intensity = 2.425(hi/Hr) Process from Point/Station 14.000 to Point/Station 15.000 **** INITIAL AREA EVALUATION **** Initial area flow distance = 540.000(Ft.) Top (of initial area) elevation = 1080.900(Ft.) Bottom (of initial area) elevation = 1076.480(Ft.) Difference in elevation = 4.420(Ft.) Slope = 0.00819 s(percent)= 0.82 TC = k(0.370)*[(length^3)/(elevation change)]^0.2 Initial area time of concentration= 11.983 min. Rainfall intensity = 3.153(In/Hr) fora 100.0 year storm CONDOMINIUM subarea type Runoff Coefficient = 0.870 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 3) = 80.00 Pervious area fraction = 0.350; Impervious fraction = 0.650 Initial subarea runoff= 5.458(CFS) Total initial stream area = 1.990(Ac.) Pervious area fraction = 0.350 Process from Point/Station 15.000 to Point/Station i., 16.000 I -.T Pipe length = 20.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 5.458(CFS) Nearest computed pipe diameter =si 9.00(In.) Calculated individual pipe flow = ' `5.458(CFS) Normal flow depth in pipe = 5.18(In.) Flow top width inside pipe = 8.90(In.) Critical depth could not be calculated. Pipe flow velocity = 20.72(Fds) Travel time through pipe = 0.02 min. Time of concentration (TC) = 12.00 min. ++++++++++++++++F�T++++t+++++++++++-r.+++++++++++++++++++++++++++ Process from Point/Station 15.000 to Point/Station 16.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: I in normal stream number 2 Stream flow area = 1.990(Ac.) Runoff from this stream = 5.458(CFS) Time of concentration = 12.00 min. Rainfall intensity = 3.151(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (min) (In/Hr) 1 36.592 19.32 2.425 2 5.458 12.00 3.151 Largest stream flow has longer time of concentration Qp = 36.592 + sum of Qb Ia/Ib 5.458 * 0.770 = 4.200 Qp = 40.792 Total of 2 streams to confluence: Flow rates before confluence point: 36.592 5.458 Area of streams before confluence: 15.860 1.990 Results of confluence: Total flow rate = 40.792(CFS) Time of concentration = 19.317 min. Effective stream area after confluence = 17.850(Ac.) Process from Point/Station 16.000 to Point/Station ... 18.000 **** PIPEFLOW TRAVEL TIME (Program estimated size) **** i° ?U streamoint/station elevation'= - P P ,..•10,65:800(Ft:)�-,-- _____ _ �dcY... No. of pipes = 1 Required pipe flow = 40.792(CFS) Nearest computed pipe diameter = 36.00(In.) Y-I'p Calculated individual pipe flow = 40.792(CFS) Normal flow depth in pipe= 25.83(In.) Flow top width inside pipe= 32.42(In.) Critical Depth= 24.95(In.) Pipe flow velocity = 7.51(Ft/s) Travel time through pipe = 0.09 min. Time of concentration (TC) = 19.41 min. ++++++++++++++++++++++++++++++++++++i -+++++++++++++F+++++++++++++++++++ Process from Point/Station 16.000 to Point/Station 18.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: I in normal stream number 1 Stream flow area = 17.850(Ac.) Runoff from this stream = 40.792(CFS) Time of concentration = 19.41 min. Rainfall intensity = 2.419(In/Hr) +++ '� ,++++++++++++++=++++++ Process from Point/Station 17.000 to Point/Station 18.000 **** INITIAL AREA EVALUATION **** Initial area flow distance = 530.000(Ft.) Top (of initial area) elevation = 1078.800(Ft.) Bottom (of initial area) elevation = 1076.000(Ft.) Difference in elevation = 2.800(Ft.) Slope = 0.00528 s(percent)= 0.53 TC = k(0.370)*[(length^3)/(elevation change)]10.2 Initial area time of concentration = 12.982 min. Rainfall intensity = 3.017(In/Hr) fora 100.0 year storm CONDOMINIUM subarea type Runoff Coefficient = 0.869 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 3) = 80.00 Pervious area fraction = 0.350; Impervious fraction = 0.650 Initial subarea runoff= 4.718(CFS) Total initial stream area = 1.800(Ac.) Pervious area fraction = 0.350 Process from Point/Station 17.000 to Point/Station 18.000 **** CONFLUENCE OF MINOR STREAMS **** Time of concentration = 12.98 min. Rainfall intensity = 3.017(In/14r) .5 Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (min) (In/Hr) 1 40.792 19.41 2.419 2 4.718 12.98 3.017 Largest stream flow has longer time of concentration Qp = 40.792 + sum of Qb Ia/lb 4.718 " 0.802 = 3.782 Qp = 44.574 Total of 2 streams to confluence: Flow rates before confluence point: 40.792 4.718 Area of streams before confluence: 17.850 1.800 Results of confluence: Total flow rate = 44.574(CFS) Time of concentration = 19.406 min. Effective stream area after confluence = 19.650(Ac.) End of computations, total study area = 19.65 (Ac.) The following figures may be used for a unit hydrograph study of the same area. Area averaged pervious area fraction(Ap) = 0.350 Area averaged RI index number = 62.5 Riverside County Rational Hydrology Program CIVILCADD/CIVILDESIGN Engineering Software,(c) 1989 - 1997 Version 5.0 Rational Hydrology Study Date: 02/12/99 File:53960A.out TRACT 28832 - PRESLEY HOMES ********* Hydrology Study Control Information ********** English (in -lb) Units used in input data file SB&O, Inc., San Diego, California - SIN 714 Rational Method Hydrology Program based on Riverside County Flood Control & Water Conservation District 1978 hydrology manual Storm event (year) = 10.00 Antecedent Moisture Condition = 2 Standard intensity -duration curves data (Plate D-4.1) For the [ Murrieta,Tmc,Rnch Callorco ] area used. 10 year storm 10 minute intensity= 2.360(In/Hr) 10 year storm 60 minute intensity = 0.880(In/Hr) 100 year storm 10 minute intensity = 3.480(In/Hr) 100 year storm 60 minute intensity = 1.300(In/Hr) Storm event year= 10.0 Calculated rainfall intensity data: 1 hour intensity = 0.880(In/Hr) Slope of intensity duration curve = 0.5500 rocess fromPoint/Station.1.000 to Point/Station 2.000 EVALUATIONINITIAL AREA Initial area flow distance = 1000.000(Ft.) Top (of initial area) elevation = 1105.000(Ft.) Bottom (of initial area) elevation = 1084.720(Ft.) Difference in elevation = 20.280(Ft.) Slope = 0.02028 s(percent)= 2.03 TC = k(0.370)*[(length^3)/(elevation change)]^0.2 Initial area time of concentration = 12.788 min. Rainfall intensity = 2.059(In/Hr) for a 10.0 year storm CONDOMINIUM subarea type .. Runoff Coefficient = 0.812 Decimal fractionsoil gr6up A,=0.000. Decimal fraction s6il,group•B =_0.500 :Decimal fractionsoil 'group C` -.O1.500 j: .....f�:'' ..11__-�_1G__i-__.__-t__-._T_n nnn:..�?.,'`.f.}.J%):`o�.l«Lc=: p•�•y1<_ait.:,:..`.a '';•. - :.Yi RI index for soil(AMC 2) = 62.50 Pervious area fraction = 0.350; Impervious fraction = 0.650 Initial subarea runoff = 4.865(CFS) Total initial stream area = 2.910(Ac.) Pervious area fraction = 0.350 +++++++++ +++++++++i FF++r 1ll1++1 11a Process from Point/Station 2.000 to Point/Station 3.000 **** STREET FLOW TRAVEL TIME + SUBAREA FLOW ADDITION **** Top of street segment elevation = 1084.720(Ft.) End of street segment elevation = 1082.260(Ft.) Length of street segment = 420.000(Ft.) Height of curb above gutter flowline = 6.0(In.) Width of half street (curb to crown) = 16.000(Ft.) Distance from crown to crossfall grade break = 14.500(Ft.) Slope from gutter to grade break (v/hz) = 0.020 Slope from grade break to crown (v/hz) = 0.020 Street flow is on [2] side(s) of the street Distance from curb to property line = 5.000(Ft.) Slope from curb to property line (v/hz) = 0.020 Gutter width = 1.500(Ft.) Gutter hike from flowline = 1.500(In.) Manning's N in gutter= 0.0150 Manning's N from gutter to grade break = 0.0 15 0 Manning's N from grade break to crown = 0.0200 Estimated mean flow rate at midpoint of street = 7.390(CFS) Depth of flow = 0.390(Ft.), Average velocity = 1.640(Ft/s) Streetflow hydraulics at midpoint of street travel: Halfstreet flow width = 14.770(Ft.) Flow velocity = 1.64(Ft/s) Travel time = 4.27 min. TC = 17.06 min. Adding area flow to street CONDOMINIUM subarea type Runoff Coefficient = 0.801 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 2) = 62.50 Pervious area fraction = 0.350; Impervious fraction = 0.650 Rainfall intensity = 1.758(In/IIr) fora 10.0 year storm Subarea runoff = 4.254(CFS) for 3.020(Ac.) Total runoff = 9.120(CFS) Total area = 5.930(Ac.) Street flow at end of street = ' 9.120(CFS) Half street flow at end of street = 4.560(CFS) Depth of flow = 0.416(Ft.), Average velocity = 1.726(Ft/s) .- a..-�:1.. .e- .e.17 P.. , ...r ...0 t... ... .y..ca... 10 I MR- yMM1Si]Y.+e "4+++++++++i-+++++i-+++++++++++i-++rm—r—rr++i—F++++-f-+++++++++++++-H-+++ Process from Point/Station 3.000 to Point/Station 8.000 **** PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 1078.760(Ft.) Downstream point/station elevation = 1076.600(Ft.) Pipe length = 15.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 9.120(CFS) Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow = 9.120(CFS) Normal flow depth in pipe = 7.22(In.) Flow top width inside pipe= 11.75(In.) Critical depth could not be calculated. Pipe flow velocity = 18.48(Ft/s) Travel time through pipe= 0.01 min. Time of concentration (TC) = 17.07 min. Process from Point/Station 3.000 to Point/Station 8.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 5.930(Ac.) Runoff from this stream = 9.120(CFS) Time of concentration = 17.07 min. Rainfall intensity = 1.757(In/Hr) ++i-+i-i--rT++++++++++++++++++++-F++++++f-�-HT++++ Process from Point/Station 5.000 to Point/Station 6.000 **** INITIAL AREA EVALUATION **** Initial area flow distance = 1000.000(Ft.) Top (of initial area) elevation= 1100.100(Ft.) Bottom (of initial area) elevation = 1084.720(Ft.) Difference in elevation = 15.380(Ft.) Slope = 0.01538 s(percent)= 1.54 TC = k(0.370)*((length^3)/(elevation change)]^0.2 Initial area time of concentration= 13.515 min. Rainfall intensity = 1.998(In/Hr) fora 10.0 year storm CONDOMINIUM subarea type Runoff Coefficient = 0.810 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 2) = 62.50 Pervious area fraction =_-0.350; Impervious fraction = 0.650, Initial subarea runoff = Totall initial '.Pervious area.fraction,= 0:35QS l; 'i'C 1. IVi f.l •-C4• +t-Ftp'-Fttt-Fti--'r'rt�r-r�-r�-r�rTT rttttttttti--f--f++ttttt Process from Point/Station 6.000 to Point/Station 7.000 **** STREET FLOW TRAVEL TIME +SUBAREA FLOW ADDITION **** Top of street segment elevation = 1084.720(Ft.) End of street segment elevation = 1082.300(Ft.) Length of street segment = 425.000(Ft.) Height of curb above gutter flowline = 6.0(In.) Width of half street (curb to crown) = 16.000(Ft.) Distance from crown to crossfall grade break = 14.500(Ft.) Slope from gutter to grade break (v/hz) = 0.020 Slope from grade break to crown (v/hz) = 0.020 Street flow is on [2] side(s) of the street Distance from curb to property line = 5.000(Ft.) Slope from curb to property line (v/hz) = 0.020 Gutter width = 1.500(Ft.) Gutter hike from flowline = 1.500(In.) Manning's N in gutter= 0.0150 Manning's N from gutter to grade break = 0.0150 Manning's N from grade break to crown = 0.0200 Estimated mean flow rate at midpoint of street = 4.215(CFS) Depth of flow = 0.333(Ft.), Average velocity = 1.422(Ft/s) Streetflow hydraulics at midpoint of street travel: Halfstreet flow width= 11.879(Ft.) Flow velocity = 1.42(Ft/s) Travel time = 4.98 min. TC = 18.50 min. Adding area flow to street CONDOMINIUM subarea type Runoff Coefficient = 0.798 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 2) = 62.50 Pervious area fraction = 0.350; Impervious fraction = 0.650 Rainfall intensity = 1.681(In/Hr) fora 10.0 year storm Subarea runoff= 1.570(CFS) for 1.170(Ac.) Total runoff = 4.839(CFS) Total area = 3.190(Ac.) Street flow at end of street = 4.839(CFS) Half street flow at end of street = 2.419(CFS) Depth of flow = 0.346(Ft.), Average velocity = 1.468(Ft/s) Flow width (from curb towards crown)= 12.556(Ft.) Process from Point/Station 7.000 to Point/Station —, ;: 8.000 **** PIPEFLOW TRAVEL TIME (Program estimated size) **** ilnstream noint/station eledation=:a107R_R00(Ft.l'; t,io-+ ice:.," ' ' i •" , :ia; t ... rvaNi.:d.N._Y�S. �..v: i <. ,::+J.+Cer;•4;:;:ix'n=x.. - _. <., No. of pipes = 1 Required pipe flow = 4.839(CFS) Nearest computed pipe diameter = 9.00(In.) Calculated individual pipe flow = 4.839(CFS) Normal flow depth in pipe = 7.27(In.) Flow top width inside pipe= 7.10(In.) Critical depth could not be calculated. Pipe flow velocity = 12.66(Ft/s) Travel time through pipe = 0.03 min. Time of concentration (TC) = 18.53 min. ++++++++++++++++++++++++H H H R H i++++++++++....+++++++++++++++++++++ Process from Point/Station 7.000 to Point/Station 8.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 3.190(Ac.) Runoff from this stream = 4.839(CFS) Time of concentration = 18.53 min. Rainfall intensity = 1.679(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (min) (In/Hr) 1 9.120 17.07 1.757 2 4.839 18.53 1.679 Largest stream flow has longer or shorter time of concentration Qp = 9.120 + sum of Qa Tb/Ta 4.839 * 0.921 = 4.457 Qp = 13.577 Total of 2 streams to confluence: Flow rates before confluence point: 9.120 4.839 Area of streams before confluence: 5.930 3.190 Results of confluence: Total flow rate = 13.577(CFS) Time of concentration = 17.069 min. Effective stream area after confluence = 9.120(Ac.) Process from Point/Station 8.000 to Point/Station 13.000 **** PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = , 1076.600(Ft.) Nearest computed pipe diameter = 21.00(In.) Calculated individual pipe flow = 13.577(CFS) Normal flow depth in pipe = 13.85(In.) Flow top width inside pipe = 19.90(In.) Critical Depth = 16.46(In.) Pipe flow velocity = 8.07(Ft/s) Travel time through pipe = 1.37 min. Time of concentration (TC) = 18.44 min. ;A' Y LY,ppFk��biy.. ++++++rrm!-+++++i-#-+++-I-{--H-+++++-I--r-r+t-r-r-f-i-+H-I-f-+++++++++++ Process from Point/Station 8.000 to Point/Station 13.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 9.120(Ac.) Runoff from this stream = 13.577(CFS) Time of concentration = 18.44 min. Rainfall intensity = 1.684(In/Hr) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Process from Point/Station 9.000 to Point/Station 10.000 **** INITIAL AREA EVALUATION **** Initial area flow distance = 750.000(Ft.) Top (of initial area) elevation = 1090.300(Ft.) Bottom (of initial area) elevation = 1077.730(Ft.) Difference in elevation = 12.570(Ft.) Slope = 0.01676 s(percent)= 1.68 TC = k(0.370)*[(length^3)/(elevation change)]^0.2 Initial area time of concentration = 11.841 min. Rainfall intensity = 2.148(In/Hr) for a 10.0 year storm CONDOMINIUM subarea type Runoff Coefficient = 0.815 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 2) = 62.50 Pervious area fraction = 0.350; Impervious fraction = 0.650 Initial subarea runoff = 8.400(CFS) Total initial stream area = 4.800(Ac.) Pervious area fraction = 0.350 Process from Point/Station 10.000 to Point/Station 13.000 **** PIPEFLOW TRAVEL TIME (Program estimated size) !*** Upstream point/station elevation = 1074.260(Ft.) _> <.; ;;a,.:, ..:, {•v ilyx;^;.Downstreampoint/stationelevation_ ♦ :uifS:➢:�� ;t,; t . mYii•Y•i•w:.w..,c _ aPipe length''0.03NIrS ,Y�,:,1; Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow = 8.400(CFS) Normal flow depth in pipe= 6.28(In.) Flow top width inside pipe= 11.99(In.) Critical depth could not be calculated. Pipe flow velocity = 20.17(Ft/s) Travel time through pipe = 0.02 min. Time of concentration (TC) = 11.86 min. + + ++++ Process from Point/Station 10.000 to Point/Station 13.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 4.800(Ac.) Runoff from this stream = 8.400(CFS) Time of concentration= 11.86 min. Rainfall intensity = 2.146(In/Hr) +++r i i ! i +-F++ +++++-F+-4-i-+++++++++++++FFA-*-+++ Process from Point/Station 11.000 to Point/Station 12.000 **** INITIAL AREA EVALUATION **** Initial area flow distance= 610.000(Ft.) Top (of initial area) elevation = 1082.800(Ft.) Bottom (of initial area) elevation = 1078.260(Ft.) Difference in elevation = 4.540(Ft.) Slope = 0.00744 s(percent)= 0.74 TC = k(0.370)*[(length^3)/(elevation change)]^0.2 Initial area time of concentration = 12.823 min. Rainfall intensity = 2.056(In/Hr) fora 10.0 year storm CONDOMINIUM subarea type Runoff Coefficient = 0.812 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 2) = 62.50 Pervious area fraction = 0.350; Impervious fraction = 0.650 Initial subarea runoff = 3.238(CFS) Total initial stream area = 1.940(Ac.) Pervious area fraction = 0.350 Process from Point/Station 12.000 to Point/Station 13.000 **** PIPEFLOW TRAVEL TIME (Program estimated size) .. Upstream point/station elevation =Downstream bindstation""';elevation. -1069:500 t: :. r:, -p-.s.._�.�,.,;.„ (F)_.. �:::c:a'}Lai 25.00 f. lvlanntri s N; �.A.0 13 a;ii = (� a 5(ea+' ya• s,•. -'7': N?:.;4Z Wn of ninPC ='.1,!R II11rPlI .T1TP i1(1W:=.11 '.FQI i'+tir` `."t;tz"`�'S•tStX�_•?�i'�:1+3e".5 Vit.. cyte � Nearest computed pipe diameter = 9.00(In.) Calculated individual pipe flow= 3.238(CFS) Normal flow depth in pipe = 4.22(In.) Flow top width inside pipe = 8.98(In.) Critical depth could not be calculated. Pipe flow velocity = 15.90(Ft/s) Travel time through pipe = 0.03 min. Time of concentration (TC) = 12.85 min. Process from Point/Station 12.000 to Point/Station 13.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 3 Stream flow area = 1.940(Ac.) Runoff from this stream = 3.238(CFS) Time of concentration = 12.85 min. Rainfall intensity = 2.054(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (min) (In/Hr) 1 13.577 18.44 1.684 2 8.400 11.86 2.146 3 3.238 12.85 2.054 Largest stream flow has longer time of concentration Qp = 13.577 + sum of Qb Ia/lb 8.400 * 0.784 = 6.589 Qb Ia/Ib 3.238* 0.820= 2.655 Qp = 22.821 Total of 3 streams to confluence: Flow rates before confluence point: 13.577 8.400 3.238 Area of streams before confluence: 9.120 4.800 1.940 Results of confluence: Total flow rate = 22.821(CFS) Time of concentration = 18.442 min. Effective stream area after confluence = 15.860(Ac.) Process from Point/Station 13.000 to Point/Station ' 16.000 **** PIPEFLOW-TRAVEL .TIME (Program estimated size) *!**_.` ro- ;> •_ . [`!vY•'�.... s.. �. Yy_ - ...._... _��.-..if vr....��S�e .f. FI. :. ..a.`�1'u.r ".Y :� i �`'. ~FI �.. 1>.F ....�...-._ ... _. .. .'Y-� _. •'1-,t Pipe length = 650.00(Ft.) Manning's N= 0.013 �. No. of pipes = 1 Required pipe flow = 22.821(CFS) gia' Nearest computed pipe diameter = 30.00(In.) Calculated individual pipe flow = 22.821(CFS) ,Normal flow depth in pipe = 21.84(In.) Flow top width inside pipe = 26.70(In.) Critical Depth = 19.50(In.) Pipe flow velocity = ' 5.96(Ft/s) Travel time through pipe= 1.82 min. Time of concentration (TC) = 20.26 min. +++++++++++++++++++++++++H+F++++++++++++++++++++++++++++H-F++++++++++ Process from Point/Station' 13.000 to Point/Station 16.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 15.860(Ac.) Runoff from this stream = 22.821(CFS) Time of concentration = 20.26 min. Rainfall intensity = 1.599(In/Hr) +i-F-F-{-#--r-mTrTi-+++++ ++++++++++++++++r+r++r++ 1 1 1 Process from Point/Station 14.000 to Point/Station 15.000 **** INITIAL AREA EVALUATION **** Initial area flow distance = 540.000(Ft.) Top (of initial area) elevation = 1080.900(Ft.) Bottom (of initial area) elevation = 1076.480(Ft.) Difference in elevation = 4.420(Ft.) Slope = 0.00819 s(percent)= 0.82 TC = k(0.370)*[(length^3)/(elevation change)]^0.2 Initial area time of concentration= 11.983 min. Rainfall intensity = 2.134(In/Hr) fora 10.0 year storm CONDOMINIUM subarea type Runoff Coefficient = 0.814 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 2) = 62.50 Pervious area fraction = 0.350; Impervious fraction = 0.650 Initial subarea runoff = 3.458(CFS) Total initial stream area = 1.990(Ac.) Pervious area fraction = 0.350 Process from Point/Station `, : 15.000 to Point/Station _. 16.000. ' §�IV4p'q°^y Pipe length = 20.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 3.458(CFS) Nearest computed pipe diameter = 9.00(In.) Calculated individual pipe flow = 3.458(CFS) Normal flow depth in pipe = 3.96(In.) Flow top width inside pipe = 8.93(In.) Critical depth could not be calculated. Pipe flow velocity = 18.50(Ft/s) Travel time through pipe = 0.02 min. Time of concentration (TC) = 12.00 min. ?v•e+ ... ✓ .. ..ury ..f .ry ..-..Ai'�.t �rerti.w.e ,HT++++++++++++++ Process from Point/Station 15.000 to Point/Station 16.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 1.990(Ac.) Runoff from this stream = 3.458(CFS) Time of concentration= 12.00 min. Rainfall intensity = 2.133(ln/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (min) (In/Hr) 1 .22.821 20.26 1.599 2 3.458 12.00 2.133 Largest stream flow has longer time of concentration Qp = 22.821 + sum of Qb Ia/Ib 3.458 * 0.750 = 2.593 Qp = 25.413 Total of 2 streams to confluence: Flow rates before confluence point: 22.821 3.458 Area of streams before confluence: 15.860 1.990 Results of confluence: Total flow rate = 25.413(CFS) Time of concentration = 20.258 min. Effective stream area after confluence = 17.850(Ac.) T Process from Point/Station 16.000 to Point/Station 18.000 * * * * PIPEFLOW TRAVEL TIME (Program estimated size) * * * * yam. ,t.. •_ No. ofP pipes = 1 Required P'Pe flo+25.413(CFS) ) Nearest computed pipe diameter = 30.00(In.) Calculated individual pipe flow = 25.413(CFS) Normal flow depth in pipe = 21.75(In.) Flow top width inside pipe = 26.79(In.) Critical Depth = 20.60(In.) Pipe flow velocity = 6.66(Ft/s) Travel time through pipe = O.1 Q min. Time of concentration (TC) = 20.36 min. ♦. ._ CJS•. r> �'� +++++++++++++++++++++++++++++++++++++++++iH ++++++++++++++++++++++++ Process from Point/Station 16.000 to Point/Station 18.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 17.850(Ac.) Runoff from this stream = 25.413(CFS) Time of concentration = 20.36 min. Rainfall intensity = 1.595(In/Hr) +++++++++++++++++;-;--F-i-++++rte,--r++++ +++++++. H H H H Process from Point/Station 17.000 to Point/Station 18.000 **** INITIAL AREA EVALUATION **** Initial area flow distance = 530.000(Ft.) Top (of initial area) elevation = 1078.800(Ft.) Bottom (of initial area) elevation = 1076.000(Ft.) Difference in elevation = 2.800(Ft.) Slope = 0.00528 s(percent)= 0.53 TC = k(0.370)*[(length^3)/(elevation change)]^0.2 Initial area time of concentration = 12.982 min. Rainfall intensity = 2.042(In/Hr) fora 10.0 year storm CONDOMINIUM subarea type Runoff Coefficient = 0.811 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 2) = 62.50 Pervious area fraction = 0.350; Impervious fraction = 0.650 Initial subarea runoff= 2.983(CFS) Total initial stream area = 1.800(Ac.) Pervious area fraction = 0.350 +++++++ Process from Point/Station 17.000 to Point/Station 18.000 **** CONFLUENCE OF MINOR STREAMS **** {4. Along Main l Runoff r Time of concentration = 12:98 min: . Rainfall intensity = 2.042 0 Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (min) (In/Hr) 1 25.413 20.36 1.595 2 2.983 12.98 2.042 Largest stream flow has longer time of concentration Qp = 25.413 + sum of Qb Ia/Ib 2.983 * 0.781 = 2.329 Qp = 27.742 Total of 2 streams to confluence: Flow rates before confluence point: 25.413 2.983 Area of streams before confluence: 17.850 1.800 Results of confluence: Total flow rate = 27.742(CFS) Time of concentration= 20.358 min. Effective stream area after confluence = 19.650(Ac.) End of computations, total study area = 19.65 (Ac.) The following figures may be used for a unit hydrograph study of the same area. Area averaged pervious area fraction(Ap) = 0.350 Area averaged RI index number = 62.5 r F.. ''^r'C._,... ��e.'.. ... .. •:+`_r:-. .. Y.�' _.,. ,..%:i+'r:_?CF•..�_..._.-__..'.f�FKxY�i�.p?�.'�'. 4i.''�'R-4:��i�rt�WSy ..r,Ly....'.733n,:.1 0 INTRODUCTION The project site, Vail Ranch - Village 3 (Tract 28832, formerly Tract 23174) is a proposed 152 unit detached condominium project and is located southeast of the City of Temecula in the County of Riverside, California, and is bounded by the Temecula Creek to the north, Overland Trail to the south, Redhawk Parkway to the west, and to the east by Tract 23174-6. The site area being developed is approximately 21.4 acres. Tract 23174 is comprised of 4 lots'. Lot 1 is open space adjacent to Redhawk Parkway, lot 2 is the future swim and tennis club, lot 3 is the proposed development and lot 4 is Paseo Park on the east end of the property. Present land uses surrounding the property are residential. Existing zoning for the property is residential. BACKGROUND HYDROLOGY INFORMATION This piece of property was leftover from the multi -phase Tract 23174 development. Lot 3 was rough graded to sheet Flow to the northwest comer where a 30" rcp pipe was installed and connected to the channel. This existing connection will be used to drain the proposed improvements. There are existing storm drain facilities in Overland Trail and under Paseo Park which will not be affected by this development. The design water surface elevation for Temecula Creek for a 100 year storm is 1061.17. This information was taken from the rough grading plans prepared by Ranpac Engineering Corporation dated August 30, 1991. METHODOLOGY Hydrology calculations were performed using the Rational Method in accordance with the County of Riverside Hydrology Manual dated April 1978, utilizing CIVIL CADD/CIVIL DESIGN software version 5.1. The RD4412 computer program from Los Angeles County Public Works was used to analyze pipe flow and calculate water surface elevations (hydraulic grade line). SUMMARY After approximating rough catch basin locations based on 2.5 cfs per acre and the street capacities, street profiles were determined and pad elevations were set. Tributary areas were then determined (see hydrology map) and the hydrology program was used to calculate Q10 and Q100 for the proposed development. Refinements were made to the catch basin locations, street profiles and pad elevations based on the results from the first trial run. After final hydrology runs were made for Q10 and Q100, catch basins were sized and the hydraulic analysis began. Hydraulic design followed the Los Angeles County Hydraulic Design Manual. Pipes were sized to meet minimum freeboard requirements at the catch basins. Street capacity charts showing the relationship between Q and depth of flow are included near the end of the report for various street grades. These are used to determine where catch basins are needed in conformance with Plate A-2 (Flood Protection Criteria) of the hydrology manual. Street profiles were designed with these locations in mind to make effecient use of them. Since the private streets do not have a right-of-way, we placed catch basins at the locations where the 100 -year flood exceeded top of curb, therefore our design has an added factor of safety. At sump locations where there is a chance of clogging and excessive ponding, we have designed the street profiles such that there are overflow elevations which are at least V below the pad elevations within the inundation limits. The catch basin design sheet shows the calculation for each inlet based on the Q and the allowable depth of ponding. The formulas are taken from the nomograph (Table 2.6-0651) from the Los Angeles County Road Department. The nomograph is based on the orifice equation where C equals 0.54. Drainage areas, pipe line numbers and node numbers corresponding to the hydrology and hydraulic calculations are shown on the attached Hydrology Map. J 2 Riverside County Rational Hydrology Program CIVILCADD/CIVILDESIGN Engineering Software,(c) 1989 - 1997 Version 5.0 Rational Hydrology Study Date: 02/04/99 File:53960.out TRACT 28832 - PRESLEY HOMES ------------------------------------------------------------------------ ********* Hydrology Study Control Information ********** English (in -lb) Units used in input data file SB&O, Inc., San Diego, California - S/N 714 Rational Method Hydrology Program based on Riverside County Flood Control & Water Conservation District 1978 hydrology manual Storm event (year) = 100.00 Antecedent Moisture Condition = 3 Standard intensity -duration curves data (Plate D-4.1) For the [ Murrieta,Tmc,Rnch Callorco ] area used. 10 year storm 10 minute intensity = 2.360(In/Hr) 10 year storm 60 minute intensity = 0.880(In/Hr) 100 year storm 10 minute intensity = 3.480(In/Hr) 100 year storm 60 minute intensity = 1.300(In/Hr) Storm event year= 100.0 Calculated rainfall intensity data: 1 hour intensity = 1.300(In/Hr) Slope of intensity duration curve = 0.5500 Process from Point/Station 1.000 to Point/Station 2.000 **** INITIAL AREA EVALUATION **** Initial area flow distance = 1000.000(Ft.) Top (of initial area) elevation = 1105.000(Ft.) Bottom (of initial area) elevation = 1084.720(Ft.) Difference in elevation = 20.280(Ft.) Slope = 0.02028 s(percent)= 2.03 TC = k(0.370)*[(length^3)/(elevation change)]^0.2 Initial area time of concentration = 12.788 min. Rainfall intensity = 3.042(In/Hr) fora 100.0 year storm CONDOMINIUM subarea type Runoff Coefficient = 0.869 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500., Decimal fraction soilou C g? p = `; ,,y..> -iter :H.;.d; "e� }t_` �LL•,;�•; Decimalfrachon'soil aroun.D.-,0.000,.-Y„rca.;;�I�,,,.ia Initial subarea runoff = 7.692(CFS) Total initial stream area = 2.910(Ac.) Pervious area fraction = 0.350 Process from Point/Station 2.000 to Point/Station 3.000 **** STREET FLOW TRAVEL TIME+ SUBAREA FLOW ADDITION **** Top of street segment elevation = 1084.720(Ft.) End of street segment elevation = 1082.260(Ft.) Length of street segment = 420.000(Ft.) Height of curb above gutter flowline = 6.0(In.) Width of half street (curb to crown) = 16.000(Ft.) Distance from crown to crossfall grade break = 14.500(Ft.) Slope from gutter to grade break (v/hz) = 0.020 Slope from grade break to crown (v/hz) = 0.020 Street flow is on [2] side(s) of the street Distance from curb to property line = 5.000(Ft.) Slope from curb to property line (v/hz) = 0.020 Gutter width = 1.500(Ft.) Gutter hike from flowline = 1.500(In.) Manning's N in gutter= 0.0150 Manning's N from gutter to grade break = 0.0150 Manning's N from grade break to crown = 0.0200 Estimated mean flow rate at midpoint of street = 11.684(CFS) Depth of flow = 0.442(Ft.), Average velocity= 1.905(Ft/s) Note: depth of flow exceeds top of street crown. Streetflow hydraulics at midpoint, of street travel: Halfstreet flow width = 16.000(Ft.) Flow velocity = 1.91(Ft/s) Travel time = 3.67 min. TC = 16.46 min. Adding area flow to street CONDOMINIUM subarea type Runoff Coefficient = 0.865 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 3) = 80.00 Pervious area fraction = 0.350; Impervious fraction = 0.650 Rainfall intensity = 2.648(In/Hr) fora 100.0 year storm Subarea runoff = 6.915(CFS) for 3.020(Ac.) Total runoff = 14.607(CFS) Total area = 5.930(Ac.) Street flow at end of street = 14.607(CFS) Half street flow at end of street = 7.304(CFS) Depth of flow=. 0.470(Ft.); Average velocity= 2.082(Ft/s) Note: depth of flow exceeds top of street crown.: , 11 _Jit /L _L --l- _ _ _I .,! /1/ ,/ \ . ' ` -?$ate :•�`ra„�,=,},'�',: ,�,.., t++tt'f-+tttttrmr-rtTr-rTT'I-I'tttt+t+tt++t+t++++t+t+tt+++t+++tt+tt+ttt+t++ Process from Point/Sffition 3.000 to Point/Station 8.000 **** PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation = 1078.760(Ft.) Downstream point/station elevation = 1076.600(Ft.) Pipe length = 15.00(Ft.) Manning's N = 0.013 No. of pipes = 1 Required pipe flow = 14.607(CFS) Nearest computed pipe diameter = 15.00(In.) Calculated individual pipe flow = 14.607(CFS) Normal flow depth in pipe = 8.34(In.) Flow top width inside pipe= 14.91(In.) Critical depth could not be calculated. Pipe flow velocity = 20.84(Ft/s) Travel time through pipe= 0.01 min. Time of concentration (TC) = 16.47 min. +++++++++++++++++++++1T 1 1 1 1T H 1!11 -i-+++++,,,,,+r+++++++ Process from Point/Station 3.000 to Point/Station 8.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 5.930(Ac.) Runoff from this stream = 14.607(CFS) Time of concentration = 16.47 min. Rainfall intensity = 2.647(In/Hr) iiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiii Process from Point/Station 5.000 to Point/Station 6.000 **** INITIAL AREA EVALUATION **** Initial area flow distance= 1000.000(Ft.) Top (of initial area) elevation= 1100.100(Ft.) Bottom (of initial area) elevation = 1084.720(Ft.) Difference in elevation= 15.380(Ft.) Slope= 0.01538 s(percent)= 1.54 TC = k(0.370)*[(length^3)/(elevation change))^0.2 Initial area time of concentration = 13.515 min. Rainfall intensity = 2.951(In/Hr) fora 100.0 year storm CONDOMINIUM subarea type Runoff Coefficient = 0.868 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 3) = 80.00 Pervious area fraction =.0.350; Impervious fraction =, 0.650 Initial subarea runoff,=z; r 5.174(CFS) . Rs- _ ' x. -- .'Total Total initial strearn area ''., il`u'.v.� a:A.>^"fV t�9 .. ,�^.' . 'a:� •.p•, '.Z ."i:^.Y \','-^. .:`.;?i;;•i;,'Perviousareafraction=,, 6J, r�.:.,,•f'.^�n;;:"i'..._.(,,,.-;,,Y.<<i +++++++++++++TTTTTTTTTTTITTTTTTrTT+'�{�F'1TfTTTTTTZ l'1 11' I : ++�FTTrTTT Process from Point/Station 6.000 to Point/Station 7.000 **** STREET FLOW TRAVEL TIME + SUBAREA FLOW ADDITION **** Top of street segment elevation = 1084.720(Ft.) End of street segment elevation = 1082.300(Ft.) Length of street segment = 425.000(Ft.) Height of curb above gutter flowline = 6.0(In.) Width of half street (curb to crown) = 16.000(Ft.) Distance from crown to crossfall grade break = 14.500(Ft.) Slope from gutter to grade break (v/hz) = 0.020 Slope from grade break to crown (v/hz) = 0.020 Street flow is on [2] side(s) of the street Distance from curb to property line = 5.000(Ft.) Slope from curb to property line (v/hz) = 0.020 Gutter width = 1.500(Ft.) Gutter hike from flowline = 1.500(In.) Manning's N in gutter = 0.0150 Manning's N from gutter to grade break = 0.0150 Manning's N from grade break to crown = 0.0200 Estimated mean flow rate at midpoint of street = 6.673(CFS) Depth of flow = 0.380(Ft.), Average velocity= 1.584(Ft/s) Streetflow hydraulics at midpoint of street travel: Halfstreet flow width = 14.267(Ft.) Flow velocity = 1.58(Ft/s) Travel time = 4.47 min. TC = 17.99 min. Adding area flow to street CONDOMINIUM subarea type Runoff Coefficient = 0.863 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 3) = 80.00 Pervious area fraction = 0.350; Impervious fraction = 0.650 Rainfall intensity = 2.522(In/Hr) fora 100.0 year storm Subarea runoff = 2.547(CFS) for 1.170(Ac;) Total runoff = 7.721(CFS) Total area = 3.190(Ac.) Street flow at end of street = 7.721(CFS) Half street flow at end of street = 3.861 (CFS) Depth of flow = 0.397(Ft.), Average velocity= 1.640(Ft/s) Flow width (from curb towards crown)= 15.110(Ft.) Process from Point/Station 7.000 to Point/Station .:. 8.000 **** PIPEFLOW TRAVEL TIME (Program estimated size) **** u ♦ �Y .'I�,•f t au.udRf C _ K' V. No. of pipes I Required pipe flow = 7.721(CFS) Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow = 7.721(CFS) Normal flow depth in pipe = 7.62(In.) Flow top width inside pipe= 11.56(In.) Critical depth could not be calculated. Pipe flow velocity = 14.69(Ft/s) Travel time through pipe = 0.03 min. Time of concentration (TC) = 18.02 min. Process from Point/Station 7.000 to Point/Station 8.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 2 Stream flow area = 3.190(Ac.) Runoff from this stream = 7.721(CFS) Time of concentration = 18.02 min. Rainfall intensity = 2.520(In/Hr) Summary of stream data: Stream Flow rate TC Rainfall Intensity No. (CFS) (min) (In/Hr) 1 14.607 16.47 2.647 2 7.721 18.02 2.520 Largest stream flow has longer or shorter time of concentration Qp = 14.607:+ sum of Qa Tb/Ta 7.721 * 0.914 = 7.060 Qp= 21.667 Total of 2 streams to confluence: Flow rates before confluence point: 14.607 7.721 Area of streams before confluence: 5.930 3.190 Results of confluence: Total flow rate = 21.667(CFS) Time of concentration = 16.473 min. Effective stream area after confluence = 9.120(Ac.) ii F+++++++++ Process from Point/Station 8.000 to Point/Station 13.000 **** PIPEFLOW TRAVEL TIME (Program estimated size) **** ' •4:t.,: Nearest computed pipe diameter = 24.00(In.) Calculated individual pipe flow = 21.667(CFS) Normal flow depth in pipe = 17.20(In.) Flow top width inside pipe = 21.63(In.) Critical Depth= 19.97(In.) Pipe. flow velocity = 9.00(Ft/s) Travel time through pipe = 1.23 min. 5 Time of concentration (TC) = 17.71 min. +++++++++++++H-rr,-,-r+++++++++n,-,Hrrr H ++++++++++++++++++++++++++++++ Process from Point/Station 8.000 to Point/Station 13.000 **** CONFLUENCE OF MINOR STREAMS **** Along Main Stream number: 1 in normal stream number 1 Stream flow area = 9.120(Ac.) Runoff from this stream = 21.667(CFS) Time of concentration = 17.71 min. Rainfall intensity = 2.544(In/Hr) +++++++++++++++ i -+++++!T . . l++++++++++. H 1 +++++++++++++++++ Process from Point/Station 9.000 to Point/Station 10.000 **** INITIAL AREA EVALUATION **** Initial area flow distance = 750.000(Ft.) Top (of initial area) elevation = 1090.300(Ft.) Bottom (of initial area) elevation = 1077.730(Ft.) Difference in elevation = 12.570(Ft.) Slope = 0.01676 s(percent)= 1.68 TC = k(0.370)*[(length^3)/(elevation change)".2 Initial area time of concentration = 11.841 min. Rainfall intensity = 3.174(In/Hr) for a 100.0 year storm CONDOMINIUM subarea type Runoff Coefficient = 0.870 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 3) = 80.00 Pervious area fraction = 0.350; Impervious fraction = 0.650 Initial subarea runoff = 13.254(CFS) Total initial stream area = 4.800(Ac.) Pervious area fraction = 0.350 Process from Point/Station 10.000 to Point/Station . 13.000 **** PIPEFLOW TRAVEL TIME (Program estimated size) **** Upstream point/station elevation_-,_ Nearest computed pipe diameter = 12.00(In.) Calculated individual pipe flow = 13.254(CFS) Normal flow depth in pipe = 8.52(In.) Flow top width inside pipe = 10.89(In.) Critical depth could not be calculated.' Pipe flow velocity = 22.23(Ft/s) Travel time through pipe = 0.02 mins Time of concentration (TC) = 11.86 min. +++++++++++++++++++ 1 1 ++++++++F++++++++++++1i+++ik++-�T+�T+++++ Process from Point/Station 10.000 to Point/Station 13.000 **** CONFLUENCE OF MINOR STREAMS **** -' Along Main Stream number: 1 in normal stream number 2 Stream flow area = 4.800(Ac.) Runoff from this stream = 13.254(CFS) Time of concentration= 11.86 min. Rainfall intensity= 3.171(In/Hr) Process from Point/Station 11.000 to Point/Station 12.000 **** INITIAL AREA EVALUATION **** Initial area flow distance = 610.000(Ft.) Top (of initial area) elevation = 1082.800(Ft.) Bottom (of initial area) elevation = 1078.260(Ft.) Difference in elevation = 4.540(Ft.) Slope = 0.00744 s(percent)= 0.74 TC = k(0.370)*[(length^3)/(elevation change)]^0.2 Initial area time of concentration = 12.823 min. Rainfall intensity = 3.038(In/Hr) fora 100.0 year storm CONDOMINIUM subarea type Runoff Coefficient = 0.869 Decimal fraction soil group A = 0.000 Decimal fraction soil group B = 0.500 Decimal fraction soil group C = 0.500 Decimal fraction soil group D = 0.000 RI index for soil(AMC 3) = 80.00 Pervious area fraction = 0.350; Impervious fraction = 0.650 Initial subarea runoff = 5.120(CFS) Total initial stream area = 1.940(Ac.) Pervious area fraction = 0.350 Process from Point/Station 12.000 to Point/Station 13.000 **** PIPEFLOW TRAVEL TIME (Program estimated size) **** ) ;'_ � a5am• ':"-z"•' .dpv�F._ �`\F+"'.'.�',�,p-.r.,?h, .. r'�:`,rr ". �� `"L . .J. .. ...rr 6K'{ •..r.. .. .r.. ..,e✓.f +.. rREPT'aPC/RD4412.1 LA COUNTY PUBLIC C WORKS � STORM DRAIN ANALYSIS (INPUT) DATE: 02/05/99 PAGE 1• PROJECT: VAIL RANCH,�VILLAGE 3 (TRACT 28832) DESIGNER. D. WHITE CD L2 MAX Q ADJ Q LENGTH FL 1 FL 2 CTL/TW D W S KJ KE KM LC L1 L3 L4 Al A3 A4 J N 8 1 64.00 2 2 44 6 44.6 70.50 64.75 65 11 0 00 30. 0. 3 0.00 0.00 0.00 i 3 0 0 37. 0. 0. 5.00 0.013 2 3 40.8 40.8 39.17 65.61 65.77 0.00 30. 0. 3 0.00 0.00 0.00 0 0 11 0 0. 55. O. 4.00 0.013 2 4 36 6 36.6 327.29 65.78 67.09 0.00 30. 0. 3 0.00 0.00 0.00 0 0 0 0 0. 0. 0. 4.00 0.013 2 5 36.6 36.6 321.56 67.11 68.39 0.00 30. 0. 3 0.00 0.00 0.00 0 0 12 13 0. 45. 45. 4.00 0.013 2 6 21.7 21.7 330.24 68.41 69.73 0.00 30. 0 3 0.00 0.00 0.00 0 0 0 C 0. 0. O. 4.00 0.013 2 7 21.7 21.7 170.24 70.23 70.91 0.00 24. 0. 3 0.00 0.00 0.00 0 0 0 0 0. 0 0. 0.00 0.013 2 8 21.7 21.7 94.70 70.91 71.29 0.00 24. 0. 3 0.00 0.00 0.00 0 0 0 0 0. 0. 0. 0.00 0.013 2 9 21.7 21.7 63.92 71.29 71.54 0.00 24. 0. 3 0.00 0.00 0.00 0 10 14 0 45. 60. 0. 4.00 0.013 2 30 10.9 10.9 14.10 72.04 78.76 81.76 18. 0. 1 0.00 0.00 0.00 0 0 0 0 0. 0. 0. 0.00 0 013 2 11 5.8 5.8 19.50 67.00 72.98 75.98 18. 0. 1 0.00 0.00 0.00 4 0 0 0 0. 0. 0. 0.00 0.013 2 12 9.3 9.3 22.60 69.50 74.26 77.26 18. 0. 1 0.00 0.00 0.00 6 0 0 0 0. 0. 0. 0.00 0.013 2 13 9.3 9.3 22.60 69.50 74.26 77.26 18. 0. 1 0.00 0.00 0.00 6 0 0 0 0. 0. 0. 0.00 0.013 2 14 10.9 10.9 25.40 72.04 78.80 81.80 18. 0. 1 0.00 0.00 0.00 10 0 0 0 0. 0. 0 0.00 0.013 L�4#. .4k?':, - _ �* ..: vl.� .. S�xAlClf.t•,y y:. -sr. .:-�:-• _ ..>Z.. ... ;`y r.... .•• o�: ..Y ....Y<.✓-.��o. 'v. .a .. rrr /..r .e..t :.. . -. '.. it : r. a. -^:� :�n�..�r v.o r... e LA COUNTY PUBLIC WORKS - '" ";1�' STORM DRAIN ANALYSIS � � -_ -_� -)CREPT: SPC/RD9912 .2 : . DATE' tii 02/05/99 PAGE 1 PROJECT: VAIL RANCH - VILLAGE 3 (TRACT 28832) DESIGNER: D. WHITE LINE Q D W DN DC FLOW SF -FULL V 1 V 2 FL 1 FL 2 HG 1 HG 2 D 1 D 2 TW TW NO (CFS) (IN)(IN) (FT) (FT) TYPE (FT/FT) (FPS) (FPS) (FT) (FT) CALC CALC (FT) (FT) CALC CK REMARKS 1 HYDRAULIC GRADE LINE CONTROL = 64.00 2 44.6 30 0 2.50 2.22 SEAL 0.01182 9.7 9.1 64.75 65 11 66.97 67.95 2.22 2 84 0.00 0.00 X = 19.97 X(N) = 0.00 3 90.8 30 0 2 50 2.14 FULL 0.00989 8.3 8.3 65.61 65.77 68.80 69.19 3 19 3 42 0.00 0.00 4 36.6 30 0 2.50 2.05 FULL 0.00796 7.5 7.5 65.78 67.09 69.54 72.15 3.76 5.06 0.00 0.00 5 36.6 30 0 2.50 2 05 FULL 0.00796 7.5 7.5 67 11 68.39 72.15 74.71 5 04 6 32 0.00 0.00 6 21.7 30 0 1.75 1.58 FULL 0.00280 4.4 4.4 68 41 69 73 75.39 76.31 6 98 6.58 0.00 0.00 7 21.7 24 0 2.00 1.66 FULL 0.00920 6.9 6.9 70.23 70 91 75.90 77.46 5 67 6.55 0.00 0.00 8 21.7 24 0 2.00 1.66 FULL 0.00920 6.9 6.9 70.91 71.29 77.46 78.34 6.55 7.05 0.00 0.00 9 21.7 24 0 2.00 1.66 FULL 0.00920 6.9 6.9 71.29 71.54 78.33 78.92 7.04 7.38 0.00 0.00 10 10.9 18 0 0.39 1.26 SEAL 0.01077 6.2 6.9 72.04 78.76. 79.79 80.02 7.75 1.26 80.75 81.76 HYD JUMP X = 12.76 X(N) = 0.00 X(J) - 12.76 F(J) = 3.95 D(BJ) = 0.85 D(AJ) = 1.79 4 HYDRAULIC GRAVE LINE CONTROL = 69.36 11 5.8 18 0 0.32 0.93 SEAL 0.00305 3.3 5.1 67.00 72.98 69.36 73.91 2.36 0.93 74.30 75.98 HYD JUMP X 0.77 X(N) = 0.00 X(J) = 0.77 F(J) = 3.03 D(BJ) = 0.38 D(AJ) = 2 12 6 HYDRAULIC GRADE LINE CONTROL - 75.05 12 9.3 18 0 0.45 1.18 SEAL 0.00784 5.3 6.2 69.50 74.26 75.05 75.44 5.55 1.18 76.04 77.26 HYD JUNP X.= 18.57 X(N) = 0.00 X(J) = 18.57 F(J) 3.35 D(BJ) 0.75 D(AJ) = 1.77 6 HYDRAULIC GRADE LINE CONTROL - 75.05 13 9.3 18 0 0.45 1.18 SEAL. 0.00784 - 5.3 6.2 .. 69.50-.+74.26'? 75.05 75.44 '• 5.55 :: 1.18 76.04 77.26 HYD JUMP X ,: 18.57 ;,X(N), =j ..0.00 '�X(J)r=,e:+18 .57.'j F(J):. =;_';' }135'x-D(BJ)+. �?::Z; %g 0.75 r."r D(AJJ:eet :; 1.77 :',:: 4 ,: ':::�,,..Y:"•i; it:p" _ ..i X,- k - :.5. . ,.- ' d "' 'W. t, ', � zs ..'G . f �... rr�.. r.:"6.4a"S..s .? sr �i'i7 A. s':$".a.Nv.^.4a s �ti 7,7,0-.. � � .tz •,.T > :.. P".9.p. w- ..�CnPPFf• ..,,¢.w.. ,,,+3b. ,, "T+F"' ,• v,',. <4f'�. �.1ie•' �`a').: .tl}•, a�Clµ" �.: t}'�@�6� r.1 " ^$.P"; :*T)Y! '. .,%'-Yb. - - 1W" ..4 _ �la w: e _ T- - L4';h �°>, - '�t]`- `;}.:,�aN,w.��'i- �a LA COUNTY PUBLIC WORKS _ STORM.'DRAIN ANALYSISRE PT: SPC/RD4412.2 •yi.a:,fµ, •. DATE: 02/05/99 PAGE 2 PROJECT: VAIL RANCH - VILLAGE 3 (TRACT 28832) DESIGNER: D. WHITE LINE Q D W DN DC FLOW SF -FULL V 1 V 2 FL 1 FL 2 HG 1 HG 2 D 1 D 2 TW TW NO (CFS) (IN)(IN) (FT) (FT) TYPE (FT/FT) (FPS) (FPS) (FT) (FT) CALC CALC (FT) (FT) CALC CK REMARKS 10 HYDRAULIC GRADE LINE CONTROL 79.36 14 10.9 18 0 0.46 1.26 SEAL 0.01077 6.2 6.9 72 04 78.80 79 36 80.06 7.32 1.26 80.79 61.80 HYD JUMP X = 20.42 X(N) - 0.00 X(J) 20.42 F(J) = 4.48 D(BJ) 0.75 D(AJ) = 2.09 .:f ;� '✓IA:. : �: '. LJ�: (tY .�a.YV!t^.'•' tr}p .h '•.:4'.:... r t4-,.::='' t'K-' - ,rf;..:2f'i'.M'4.PW :•.W _ i.�:YTea m'1?:'Y ��::. "i :' ..lr'..fL;':Y y:':: j: :.`1 :; cl`j�:. �:<;<._.. - - .� Mt }}::^:,'s ,r.:+.K�,,.•av?.aF1.„r�,r"�v`:{,a.:,h;". :.5�:. •yt-._h' .l: t. ::J"S'" '1.•Y. .N¢_•.p.j• .r�%:;'.'.'{.♦ ✓L_ ..rtC r¢t'.F�'.?y, ,�. - - 1W" ..4 _ �la w: e _ T- - L4';h �°>, - '�t]`- `;}.:,�aN,w.��'i- �a �1. ;.i°•' V 1, FL I, D 1 AND HG 1 REFER TO DOWNSTREAM END V 2, FL 2, D 2 AND HG 2 REFER TO UPSTREAM END:,: .�,.y. . : X - DISTANCE IN FEET FROM DOWNSTREAM END TO POINT WHERE HG INTERSECTS SOFFIT IN SEAL CONDITION X(N) - DISTANCE IN FEET FROM DOWNSTREAM END TO POINT WHERE WATER SURFACE REACHES NORMAL DEPTH BY EITHER DRAWDOWN OR BACKWATER X(J) - DISTANCE IN FEET FROM DOWNSTREAM END TO POINT WHERE HYDRAULIC JUMP OCCURS IN LINE k F(J) - THE COMPUTED FORCE AT THE HYDRAULIC JUMP 4r D(BJ) - DEPTH OF WATER BEFORE THE HYDRAULIC JUMP (UPSTREAM SIDE) D(AJ) - DEPTH OF WATER AFTER THE HYDRAULIC JUMP (DOWNSTREAM SIDE) SEAL INDICATES FLOW CHANGES FROM PART TO FULL OR FROM FULL TO PART HYD JUMP INDICATES THAT FLOW CHANGES FROM SUPERCRITICAL TO SUBCRITICAL THROUGH A HYDRAULIC JUMP HJ 0 UJT INDICATES THAT HYDRAULIC JUMP OCCURS AT THE JUNCTION AT THE UPSTREAM END OE'T3E LINE HJ 0 DJT INDICATES THAT HYDRAULIC JUMP OCCURS AT THE JUNCTION AT THE DOWNSTREAM END OF THE LINE EOJ 2/ 5/1999 9:23 . .r,±ry ,�.j^r• .y;;,>r' qT-^[a�, r: ti-A�Sor. . •'i t'tii�T� STREET CAPACITY CHART'- INTERIOR STREETS; ' CURB HEIGHT = 6" X -SLOPE = 2.0% 32' CURB TO CURB GUTTER WIDTH = 1.5' STREET GRADE = 0.50% GUTTER HIKEUP = 0.15' MANNING'S N = 0.015 DEPTH FLOW AT WIDTH AREA HYD. RAD. REMARKS AT CURB GUTTER OF FLOW 0.15 0.13 0.0 0.113 0.068 0.16 0.14 0.5 0.130 0.060 0.17 0.16 1.0 0.153 0.057 0.18 0.19 . 1.5 0.180 0.057 0.19 0.22 2.0'410.213 0.058 . 0.20 0.27 2.5 0.250 0.060 0.21 0.32 3.0 0.293 0.062 0.22 0.39 3.5 0.340 0.065 0.23 0.46 4.0 0.393 0.068 0.24 0.55 4.5 0.450 0.072 0.25 0.64 5.0 0.513 0.076 0.26 0.75 5.5 0.580 0.080 0.27 0.88 6.0 0.653 0.084 0.28 1.01 6.5 0.730 0.088 0.29 1.16 7.0 0.813 0.092 0.30 1.33 7.5 0.900 0.097 0.31 1.51 8.0 0.993 0.101 0.32 1.70 8.5 1.090 0.106 0.33 1.92 9.0 1.193 0.110 0.34 2.15 9.5 1.300 0.115 0.35 2.39 10.0 1.413 0.119 0.36 2.66 10.5 1.530 0.124 0.37 2.94 11.0 1.653 0.128 Q 10 approaching catch basin 1 0.38 3.25 11.5 1.780 0.133 0.39 3.57 12.0 1.913 0.138 Q 10 approaching catch basin 2 0.40 3.91 12.5 2.050 0.142 0.41 4.28 13.0 2.193 0.147 0.42 4.66 13.5 2.340 0.152 Q 100 approaching catch basin 1 0.43 5.07 14.0 2.493 0.156 0.44 5.49 14.5 2.650 0.161 Q 100 approaching catch basin 2 0.45 12.11 16.0 5.620 0.171 0.46 13.28 16.0 5.940 0.180 0.47 14.49 16.0 6.260 0.190 0.48 15.74 16.0 6.580 0.200 0.49 17.03 16.0 6.900 0.209 0.50 18.35 16.0 7.220 0.219 TOTAL Q @ NODE 15 = 5.5 cfs (Q 100) & 3.5 cfs (Q 10) FROM HYDROLOGY PROGRAM TOTAL Q @ NODES 18 = 4.7 cfs (Q 100) & 3.0 cfs (Q 10) FROM HYDROLOGY PROGRAM �)'�: 'Y�1 ^.11tl ,J `•+io .n • _ .:%i` i; n-tY: ��4.e. •'(�:; !-j ., .e(L•.ti." :'�•N.Sv�.ki'{c�L ' .[. ,.. - . c`1 �� .. iL''.'?SiY.inNiI J•of Y � `t., i:.i ..'...!- % �..'.['..t4`i �\.1•. ..Gvl4 �Y - t".ir: n'*:'�le'�� iY.lY)''41�5''Tu �'}T'�'�r°�},�.'y%.�'h''�'IY.i �i'k`,f •'f��#"�,'').riY'.1•[(._'�1y.��Y'.Sl.'�t.5j��.ii '4�W':t(\. 'iµ""'le�:.Sl1.... .. - �. r`y+',CY.i�•h;.:fi:la1i"gi 3a=.'ti;.mik.5.,h er=.: SA. CURB HEIGHT = 6" GUTTER WIDTH = 1.5' GUTTER HIKEUP = 0.15' fid X-SLOPE`.'"l %0% STREET '="2ET GRADE = 0.50% MANNING'S N = 0.015 DEPTH FLOW AT WIDTH AT CURB GUTTER OF FLOW 32' CURB TO CURB REMARKS 0.15 0.13 0.0 0.113 0.068 0.16 0.14 0.5 0.130 0.060 0.17 0.16 1.0 0.153 0.057 0.18 0.19 1.5 0.180 0.057 0.19 0.22 2.0 0.213 0.058 0.20 0.27 2.5 0.250 0.060 0.21 0.32 3.0 0.293 0.062 0.22 0.39 3.5 0.340 0.065 - 0.23 0.46 4.0 0.393 0.068 0.24 0.55 4.5 0.450 0.072 0.25 0.64 5.0 0.513 0.076 0.26 0.75 5.5 0.580 0.080 0.27 0.88 6.0 0.653 0.084 0.28 1.01 6.5 0.730 0.088 . 0.29 1.16 7.0 0.813 0.092 0.30 1.33 7.5 0.900 0.097 0.31 1.51 8.0 0.993 0.101 0.32 1.70 8.5 1.090 0.106 0.33 1.92 9.0 1.193 0.110 0.34 2.15 9.5 1.300 0.115 0.35 2.39 10.0 1.413 0.119 0.36 2.66 10.5 1.530 0.124 0.37 2.94 11.0 1.653 0.128 0.38 3.25 11.5 1.780 0.133 0.39 3.57 12.0 1.913 0.138 0.40 3.91 12.5 2.050 0.142 0.41 4.28 13.0 2.193 0.147 0.42 4.66 13.5 2.340 0.152 0.43 5.07 14.0 2.493 0.156 0.44 5.49 14.5 2.650 0.161 0.45 12.11 16.0 5.620 0.171 Q 10 approaching catch basins 3 & 4 0.46 13.28 16.0 5.940 0.180 0.47 14.49 16.0 6.260 0.190 0.48 15.74 16.0 6.580 0.200 0.49 17.03 16.0 6.900 0.209 0.50 18.35 16.0 7.220 0.219 Q 100 approaching catch basins 3 & 4 TOTAL Q @ NODES 10 & 12 = 18.3 cfs (Q 100) & 11.6 cfs (Q 10) FROM HYDROLOGY PROGRAM CURB HEIGHT = 6" GUTTER WIDTH = 1.5'. GUTTER HIKEUP = 0.15' STREET CAPACITY CHART -INTERIORS: BEETS X -SLOPE = 2.0% 32' CURB TO CURB STREET GRADE = 0.80% MANNING'S N = 0.015 DEPTH FLOW AT WIDTH AREA HYD. RAD AT CURB GUTTER OF FLOW 0.15 0.17 0.0 0.113 0.068 0.16 0.18 0.5 ,^ I 0.130 0.060 0.17 0.20 1.0 '�`,a%: 0.153 0.057 0.18 0.23 1.5 0.180 0.057 0.19 0.28 2.0 0.213 0.058 0.20 0.34 2.5 0.250 0.060 0.21 0.41 3.0 0.293 0.062 0.22 0.49 3.5 0.340 0.065 0.23 0.58 4.0 0.393 0.068 0.24 0.69 4.5 0.450 0.072 0.25 0.81 5.0 0.513 0.076 0.26 0.95 5.5 0.580 0.080 0.27 1.11 6.0 0.653 0.084 . 0.28 1.28 6.5 0.730 0.088 0.29 1.47 7.0 0.813 0.092 0.30 1.68 7.5 0.900 0.097 0.31 1.91 8.0 0.993 0.101 0.32 2.16 8.5 1.090 0.106 0.33 2.43 9.0 1.193 0.110 0.34 2.72 9.5 1.300 0.115 0.35 3.03 10.0 1.413 0.119 0.36 3.36 10.5 1.530 0.124 0.37 3.72 11.0 1.653 0.128 0.38 4.11 11.5 1.780 0.133 0.39 4.52 12.0 1.913 0.138 0.40 4.95 12.5 2.050 0.142 0.41 5.41 13.0 2.193 0.147 0.42 5.90 13.5 2.340 0.152 0.43 6.41 14.0 2.493 0.156 0.44 6.95 14.5 2.650 0.161 0.45 15.32 16.0 5.620 0.171 0.46 16.80 16.0 5.940 0.180 0.47 18.32 16.0 6.260 0.190 0.48 19.90 16.0 6.580 0.200 0.49 21.54 16.0 6.900 0.209 0.50 23.22 16.0 7.220 0.219 S P; REMARKS Q 10 approaching catch basins 5 & 6 Q 100 approaching catch basins 5 & 6 TOTAL Q @ NODE 3 & 7 = 21.7 cfs (Q 100) & 13.6 cfs (Q 10) FROM HYDROLOGY PROGRAM YM' , =r. ... �,u�k - ^ _ _ '.'�11� .. .. .P.1',�r}'� r:•• - .. Siadw.�'a„l,� NN •��� � � � `fib CATCH BASIN DESIGN l USE NOMOGRAPH (PLATE 2.6-0651) FOR SUMP CONDITIONS CATCH BASIN #1 Q100 =4.7 cfs H = 5” (water allowed to pond to crown) + 4" (local depression) = 9" h = 8" (actual height of opening) from nomograph, Q/L = 1.4 L = Q/1.4 = 4.7/1.4 = 3.4' USE L=4' CATCH BASIN #2 Q100 = 5.5 cfs H = 5" (water allowed to pond to crown) + 4" (local depression) = 9" h = 5.5" (actual height of opening) from nomograph, Q/L = 1.4 L = Q/1.4 = 5.5/1.4 = 3.9' USE L = 4' CATCH BASIN #3 & #4 Q100 = 18.3 cfs (9.2 cfs per catch basin) H = 6" (water allowed to pond to top of curb) + 4" (local depression) = 10" h = 5.5" (actual height of opening) from nomograph, Q/L = 1.55 L = Q/1.55 = 9.2/1.55 = 5.9' USE L=7.0' CATCH BASIN #5 & #6 Q100 = 21.7 cfs (10.9 cfs per catch basin) H = 6" (water allowed to pond to top of curb) + 4" (local depression) = 10" h = 5.5" (actual height of opening) from nomograph, Q/L = 1.55 L=Q/1.55=10.9/1.55=7.0' ._ i USE L"= 7.0' - . 1.0 :aGelC .9 El r w w LL z .5 r cD z w .4 0 O LL 0 .F x t� W z.3 2 ' e r O S O LL 4 N z J 2 4 3 1.5 T O N 6 = w 1.0 z o 6 ,/ w I.o 0 / 5 z 6 •5 U- 0 O z �. r 8 O 5 r W T 0 4 F. o .►e�� 0 LL O 0 .2 N .6 c� w LL / 14, ¢ LJ u 1 = 3 a OB r CL 4 Q• G w O u .O6 .05 0 w .04 0 z 0 a .3 • .03 . 2 Height --�_ls..rcc. of .2 - voac.a .coo` leccl dtorculon (a)• .� .15 o. . .. - ELEVATION•'.;.':t`..;i-