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Home My WebLink About15 - Design Report - Boulder Creek - Stormwater STORM WATE R MANAGEMENT DESIGN REPORT BOULDER CREEK SUBDIVISION Prepared for: Rosa-Johnson Development, LLC. 125 Central Avenue, Bozeman, MT 59718 Prepared by: C&H Engineering and Surveying, Inc. 1091 Stoneridge Drive, Bozeman, MT 59718 (406) 587-1115 -_ V MAN f r Project Number: 14624 JUNE 2015 INTRODUCTION The Boulder Creek Subdivision is a 63 lot residential subdivision located east of Laurel Parkway and north of Annie Street. The 35.34-acre development is situated in the South Half of Section 4, Township 2 South, Range 5 East of P.M.M., Gallatin County, Montana. This project will require connection to existing City of Bozeman water and sanitary sewer systems. The software Autodesk Storm Sanitary Analysis (SSA)was used for all pipe sizing calculations in this report. The results from the model can be found in Appendix C of this report. The model report contains both input data and model run output for each drainage area, pipe, inlet and manhole. C&H developed spreadsheets were used for all other calculations including pipe outlet capacities, gutter flow depth and detention pond sizing. Each drainage area, weighted C value, total acreage and storm peak runoff was calculated using a C&H developed excel spreadsheet prior to inputting the data into SSA. The spreadsheet printouts and all other items mentioned above can be found in Appendices B, C and D. STORMWATER MANAGEMENT Design of the stormwater facilities for this project was based on the City of Bozeman Design Standards and Specifications Policy, March 2004 including Addendums I through 5. The subdivision has been divided into separate drainage areas as shown in Figure DA1 in Appendix B. A composite "C" runoff coefficient was calculated for each drainage area along with the post-development time of concentration. Inlets will be placed along roadways at intervals to ensure the gutter capacity is not exceeded (see gutter capacity spreadsheet Appendix B). Per the City of Bozeman Design Standards, storm sewer facilities shall be sized for the 25-year storm event. Curbs can flow at a depth up to 0.15 feet below the top of curb elevation. Flows were calculated at a point just upstream of the inlets to ensure adequate capacity. Detailed calculations for the composite "C" factor, time of concentration, and curb depth check for each drainage area can also be found in Appendix B. PVC pipe will be used to connect the inlets to manholes and ponds. Per City of Bozeman Design Standards,the pipe shall be sized for the 25-year storm event. The minimum pipe size shall be 12 Design Report-Page 2 of 8 inch for inlets and 15 inch for mains within the storm drain system. At the design flow, a minimum of 3 feet per second of velocity is required to prevent sedimentation in the pipe system. Each inlet will have a 9 inch sump for sediment collection as well. Detailed calculations for design flow, peak capacity, and velocity for each pipe section can be found in Appendix C along with the SSA report which details pipe and inlet results and characteristics. Retention ponds are proposed in the design to retain stormwater as it percolates into the soil and evaporates. Detention ponds are also proposed to treat stormwater prior to discharging it to Baxter Creek. Design water depth calculations did not exceed 1.5 ft. with the exception of Detention Pond 5 and existing Retention Pond 2. In cases where detention pond water depths exceeds 1.5 ft. a 4 ft. fence will be installed around the ponds perimeter. Retention ponds were sized per City of Bozeman Design Standards to handle the entire volume from the 10-year, 2-hour storm event. Detention ponds were also sized per City of Bozeman Design Standards. The pre-developed runoff rate was calculated and a discharge structure was then designed to limit the outfall from the detention pond to the pre-developed runoff rate. The release volume is subtracted from the runoff volume to calculate the required storage. The storm duration was increased in the detention pond spreadsheet until the maximum required storage was calculated. Detailed calculations for the detention and retention pond volumes can be found in the spreadsheet printout in Appendix D. STORMWATER DESIGN Stormwater runoff from the subdivision will be conveyed to one of four detention/retention facilities. A plan view of the site highlighting the drainage areas and the stormwater features is included in Appendix B (Figure DA I). The eastern side of the site will drain into Detention Pond 5 and includes drainage areas:DA 1,DA 4, DA 5, DA 6 and DA 7. The east side of the four one acre lots located in the northeast of the subdivision (DA 9) will drain to Retention Pond 7. Drainage Areas 2 and 3 located in the southeast of the site will drain to Detention Pond 6. Existing Retention Pond 2 (Detention Pond #8) which was installed as a temporary retention facility in Laurel Glen Phase 2 will be converted to a Detention facility and Drain DA 8 and DA 34E, consisting of drainage from Laurel Parkway, Design Report-Page 3 of 8 a small portion of Oak Street and Block 34 (Creekstone Condos). Major drainage features of area DA 34E were completed during Laurel Glen Phase 2. DETENTION POND #5 Detention Pond #5 will retain and release runoff from Drainage Areas DA 1, DA 4, DA 5, DA 6 and DA 7. These drainage areas combined have a total area of 14.04 acres and a composite "C" runoff coefficient of 0.48. The pre-developed runoff rate was calculated to be 1.72 cfs. (See Appendix D for detailed calculations). The storage volume was computed by increasing the storm duration and computing the runoff volume minus the release volume. The release rate is equal to the pre-developed runoff rate. The maximum storage required occurs at a storm duration of 50 minutes and is equal to 9,523 cubic feet. Detention Pond #5 has a volume of 10,262 cubic feet. An outlet structure will be constructed for the pond and will have an 18 inch outfall pipe. This pipe is sized to carry the 25 year flow as required by the City of Bozeman Design Standards. A weir will be constructed in the outlet structure to limit the runoff to the pre-developed flow rate. This weir will have a slot width of 3.4 inches to limit the discharge to 1.72 cfs. (See Appendix D for detailed calculations). DETENTION POND #5 PIPE SIZING Two separate drainage systems drain into Detention Pond #5 the north system and the southeast system. Drainage originating from the southeast of the pond from drainage area DA 1 is conveyed via a 15 inch pipe from Storm Inlet#6 to SDMH 6. The 15 inch pipe drains a total area of 4.01 acres. The time of concentration for this pipe is equal to the time of concentration of DA 1 which is 22.90 minutes. At this time of concentration, the calculated peak flow rate is 2.66 cfs. (See Appendix C for detailed calculations). This pipe has a design capacity of 5.72 cfs and a travel time of 0.15 minutes. A 15 inch pipe will be installed from SDMH 6 to SDMH 5 and will continue to convey runoff from Drainage Area 1. The pipe will be upsized to an 18" pipe downstream from Storm Inlet 5 and the rest of the pipes from this inlet to the detention pond will be sized as 18" PVC drain pipe. All pipe travel times, diameters, peak and design flow rates and times to peak flow occurrence can be found in the SSA report in Appendix C on the Pipe Results page. Storm Inlet 5 will drain runoff from Drainage Area DA 4. The system picks up more flow downstream from drainage areas DA 5 and DA 6 at inlets 4 and 3 respectively. At this location Design Report-Page 4 of 8 the system is carrying flows from all upstream drainage areas and experiences the maximum flow rate in the entire system. This pipe from Storm Inlet 3 to Detention Pond #5 is sized at 18" and has a capacity of 15.65 cfs. The pipe experiences a peak flow rate of 7.87 cfs during the model run for the 25 year COB storm event which is 50% of the total pipe capacity. Drainage from the north system originating from Oak Street and its adjacent lots also enters Detention Pond#5. Drainage area DA 7 is collected at storm inlet 1. Drainage from this inlet is conveyed to SDMH 10 and then SDMH 9 along the north side of Oak Street before it is routed into Detention Pond#5. The time to peak flow occurrence happens at 21 minutes and the inlet pipe to Detention Pond#5 experiences a maximum flow at this time of 2.04 cfs. All pipes in this section are sized at 15" PVC. (See Appendix D for detailed calculations). OUTLET STRUCTURE AND PIPING—DETENTION POND #5 An outlet structure and piping will be installed in the northwest corner of Detention Pond#5. The outlet structure will be sized per City of Bozeman Design Standards and have a slot width of 3.4 inches at the outlet weir to limit the runoff to the pre-developed runoff rate. The outlet pipe will be sized as an 18 inch pipe,which at the 1.19%design slope has a maximum capacity of 12.33 cfs. This capacity exceeds the 25 year design peak flow rate of 9.49 cfs which includes peak flow from both the north and southeast systems. As such,this outlet pipe will be adequately sized to provide overflow capacity from Detention Pond #5 into Baxter Creek. (See Appendix D for detailed detention pond calculations). DETENTION POND #6 Detention Pond #6 will retain and release runoff from Drainage Areas DA 2 and DA 3. These drainage areas combined have a total area of 4.33 acres and a composite "C" runoff coefficient of 0.52. The pre-developed runoff rate was calculated to be 0.53 cfs. (See Appendix D for detailed calculations). The storage volume was computed by increasing the storm duration and computing the runoff volume minus the release volume. The release rate is equal to the pre-developed runoff rate. The maximum storage required occurs at a storm duration of 55 minutes and is equal to 3,235 cubic feet. Detention Pond #6 has a volume of 3,601 cubic feet. An outlet structure will be constructed for the pond and will have a 15 inch outfall pipe. This pipe is sized to carry the 25 Design Report-Page 5 of 8 is sized to carry the 25 year flow as required by the City of Bozeman Design Standards. A weir will be constructed in the outlet structure to limit the runoff to the pre-developed flow rate. This weir will have a slot width of 1 inch to limit the discharge to 0.53 cfs. (See Appendix D for detailed calculations). DETENTION POND #6 PIPE SIZING Detention Pond#6 was sized in the same manner as Detention Pond#5 and carries a much smaller portion of the overall drainage from the site. Due to the site characteristics and street locations Detention Pond#5 and its associated system drains the majority of the site. Runoff from drainage areas DA 2 and DA 3 will flow into Detention Pond #6. All pipes for this section will be 15" PVC. The Storm Inlets 9 and 10 drain drainage areas DA 3 and DA 2 respectively. The pipe containing the highest flow in this system is the 37 ft. section of pipe running from Inlet 9 to Detention Pond #6. This section of pipe has a capacity of 4.57 cfs (25 year storm event) and experienced a peak flow of 2.70 efs during the model run which represents 59% of the overall capacity. OUTLET STRUCTURE AND PIPING—DETENTION POND #6 An outlet structure and piping will be installed on the northwest side of Detention Pond#6. The outlet structure will be sized per City of Bozeman Design Standards and a slot width of I inch will be used to limit the runoff to the pre-developed runoff rate. The outlet pipe will be sized as a 15 inch pipe which at the 0.54%design slope has a maximum capacity of 5.11 cfs. This exceeds the 25 year design peak flow rate of 2.70 cfs and will adequately provide overflow capacity from the detention pond. (See Appendix D for detailed detention pond calculations). DETENTION POND #8 Detention Pond #8 was originally built during Laurel Glen Phase 2 construction and was constructed as a temporary retention facility, as discussed in the C&H Design report dated October 2004. In the report the pond is referred to as Temporary Retention Pond#2. Detention Pond#8 will retain and release runoff from Drainage Areas DA 34E and DA 8. These drainage areas combined have a total area of 5.86 acres and a composite"C"runoff coefficient of 0.58. Note that the weighted "C" value of 0.72 used for the Laurel Parkway portion of DA 8 was taken directly Design Report-Page 6 of 8 from the original C&H drainage report from 2004. The pre-developed runoff rate was calculated to be 1.11 efs. (See Appendix D for detailed calculations). The storage volume was computed by increasing the storm duration and computing the runoff volume minus the release volume. The release rate is equal to the pre-developed runoff rate. The maximum storage required occurs at a storm duration of 50 minutes and is equal to 4,064 cubic feet. Detention Pond #8 has a volume of 5,543 cubic feet at a 2 ft. depth as field surveyed and calculated in Autodesk Civil 3D software. An outlet structure will be constructed in the pond and will have a 15 inch outfall pipe. This pipe is sized to carry the 25 year flow as required by the City of Bozeman Design Standards. A weir will be constructed in the outlet structure to limit the runoff to the pre-developed flow rate. This weir will have a slot width of 2.1 inches to limit the discharge to 1.08 cfs. (See Appendix D for detailed calculations). DETENTION POND #8 PIPE SIZING Runoff from drainage areas DA 8 and DA 34E will flow into Detention Pond #8. All pipes upstream of Detention Pond#8 are proposed to be 15"PVC. Drainage area DA 8 drains to Storm Inlet 8 located to the east of the site on the south side of Oak Street approximately 123 ft. from the property boundary of Boulder Creek Subdivision. The pipe containing the highest flow in this system is the 38 ft. section of pipe running from SDMH 8 to Detention Pond #8. This section of pipe has a capacity of 5.74 cfs (25 year storm event) and experienced a peak flow of 3.46 cfs during the model run which represents 61% of the overall capacity. OUTLET STRUCTURE AND PIPING—DETENTION POND #8 An outlet structure and piping will be installed on the northwest side of Detention Pond 48. The outlet structure will be sized per City of Bozeman Design Standards and a slot width of 2.1 inches will be used to limit the runoff to the pre-developed runoff rate. The outlet pipe will be sized as a 15 inch pipe which at the 0.59% design slope has a maximum capacity of 5.34 cfs. This exceeds the 25 year design peak flow rate of 4.5 cfs and will adequately provide overflow capacity from the detention pond. (See Appendix D for detailed detention pond calculations). Design Report-Page 7 of 8 LEGEND a` or o EXISTING SPOT ELEVATION U951KS A. x(100.00) PROPOSED SPOT ELEVATION CHANCIER T1 EXISTING POWER BOX[IOSimG m[PHONE BoxEXISTING ELECTRIC BOX 1XISTWC SANITARY SEWER MANHOLE Sheet 1 of I !)"' EXISTING SANITARY SEWER CLEMOUT iXY EXISTING FIRE HYDRANT SOMH 10 Itr STA 6.151(20.99Y) STORM MET 2(W)SM p.4e.70 1].OY SDMH 7 ST.0.6110 e,19T1} SOMN 9 4e' SU].(0.9] 70.801. - D m�E EXISTING WATER VALVE 4 �2� !L OUT U 1/2 64 IF OF]6'x FL OUT 64573/67(IV) R m 47Sa.52(15•) R IN([):1733.ta(f5--) � 58 1/1-RCP CULKRT W vnmi 39 EXISTING Cu'W STOP F FL OUT 47a.7l2 15 it OUT ;4131.73(1]' FL our(W}Y7]I,]p(15) N'A' I j 4 f_CT10N 1 k ( ) (fiw) ) NE 1!F SEC FION 4 OM FLARCO[NO [ ❑❑ m 'JEiiTA FERN NELSON IRAN9nONf E 1/1 CDR.SC_ •:Eiti,FERIJ NF.I:i011 FNO 5/0•RERAN ✓ Ex15nNG POWER POlf Lllr G=HE NINE.AFEEE<SAT(VAfiE C.WATER M.F.( 11gi R I't' 'E 2 m R+AnY:{ITIi[F.INE INDERS(iIJ(6U.FIE r' EIA1 tA -f1ttS7mD A JOLE' -CYY:Iva:PO'M'Eu I [� LIFE ESTATE N d C�FM P..t E v 5 EXISTING LIGHT POLE LIE E:iTA"; - 13' EXISTING STORM INLET It -DA4- ~-»` le•`-I• P N PROPOSED STORM INLET '-- -- - _ _-- - - -- a D n our(N}4734.75(15•) \ Iroln +. .''{/• [ ® PROPOSED STORM DRAIN MANHOLE t� • ij. ( .E SOMH B 4r sr I. )-A 34E : s,p I SfORI/INIET] .e' SEA 5.1/,64 1] 5'OEPM lit'HUPC C.LII4ERi PRWOSm SANITARY SETTER MA%HQ E ( ) (0. m I w INSTALL 6!Li �'�I / F,L.IN PROPOSED UNITARY SEWER CLEANOUT I OT_ R a2 7 IS-) OF Sa•%6B• ] !l W(S):17aS.e.(IV) ), 8 CPA CULVERT WITH i R OUT(W):47a524(le•)I •'�,` F.I.CUT IJ 4]_5.5] W 9 N PROPOSED WATER VALVE V I TIME' ENO I I O ` 8 NLO(:K 1 SIORMWATER / e iITCI VAINTEN.?VICE FA'_:FI.IF.NT,® PRorosf0 CURB STOP "11K ( ( iRAN77ogs L; PROPOSED FOE HYORANI .,[ j<! DE(FINBON 1 i EASEMENT I 1 ® -�� 7170DEPPA2' I y a rROPo5C0 WRIER IKII � )t0 DETENTION) � �� PROPOSED LIGHT POLE _1'4410E SANIrIPY.i1INEP PROPERTY BOUNDARY LINE ----u r „^- - / \� - EASEMENT I&? _ -l� FM --TY.-y r CUi:21.•25i3981 -- --SURROUNDING PROPERTY LINE --- - R (W):17]I, (1�)4 ` \ (� 5L161.Cy tI.li Q 'I-T a STA 2.2 2 LOT RI_ DA 9 T R ----EDGE OF WETlANO Ul I �, (/h M(Sfij� .a6 IF 1 _ D A 5 \ \ REMi�INOER T.J9•; us[MENr uNc 3 (/ ) u 4 J _x_.__g-- EXISTING FENCE (� LOT I ' L_7 f ';I iI FL m(5):A7a7.22(IY)% OHE --- EXISTING OVERHEAD ELECTRIC LINE FL OUT(N);.7]7.17(IV ( c (T� • ^++-UGE.---EXISTING UNDERGROUND ELECTRIC LINE f/) ! f,/) FL (E) 7]I. (le•) };b DA 6 i \\ I r�l �- ouT :7]i.ei p[r) \\ I I l\ ` ` z, 'r•� V -- EXISTING GAS LINE tl ( - -- ---- l ----EXISTING UNDERGROUND PHONE LINE - i 1� \ DA 4 - i 1 _7� W EXISTING OVERHEAD PHONE LINE W-PROPOSED WATER SERVICE w it: e'w-PROPOSED S WATER MAIN sum [I.,10.A +5.011) ` II -~ -" -4-SS-PROPOSED 4•SANITARY SEWER SERVICE (U4 1. 4B' S1A 7.1 .M Ia.4]R) I I ;^t -e'SS -PROPOSED BE SANITARY SEWER MAIN \ IN(SE): 12.0] SOMA],.((r46•)SIA e.4 J FL qli(NT-t .0](15-) I wt••i3 -ST-PROPOSED Slog."ER I WE PROPOSED UNDERGROUND ELECTRIC LINE :iJ iOCK 4.1].91 IS10'L FL o (q.40.69(1(IROUT(N}1710.69(1;Y" PROPOSED SWALE/RETENTION POND CONTOUR , • j Nwk4 - -� PROPOSED CURB AND GUTTER -,,,7 1 DRAINAGE AREA 1 1 Ex n.LEI BC e 1 IF I5,�1 LOT n I �LOT 5 I LOT 6 I 1 (S; 919},}7 I \ AREA NT) INLET 3, 5-1I I FAL -E, n 6 II/:iI,E 1 L0 4 a�AM 474E 10 1 `/�� F:W/ LJ ! �: ""'h .?4 4,20 +� IT15.116 NLET b ]S.N' 7 6.39 7.440 (� FL ovl a• (IV) .7�.e O� ,m7 - ,_`� -__- ��f / •��.�C4y�. '' I I MFASVRMEIJii w \\3QLY 1 ;.lil, t 4U li t. 1N Lr41.C:/ ]t011Y mLL[10 1� ] 402 9' �:LU 2 f ~ Z --•�. �r / T� I �- TW:44GA 6T L 66 Lf OF I {� ` I J/• v/d.VT ••x FL OUT("4140.20(IY) `\• lI-J ) FLA�OTEND I )f,n:.:..i - rl EIE.IJ'v O ANSIDONS - -- I - �' V'.' f--_-T I iIElENi1JN I Afi I �-- z {( POPID �V• EXISTING u7 M I LO"R. UT 1 •`�� ,� I i 1FFFO��---"'44111 2 �N z 0,4Lt!'.4 � DAL 1 EV 2 �I (� l:k:i TING I I H `Ul PCN - I it LET W R 4 �' RIM 475032 F.L. (SN)'1 4A 2 J �� r F.i_.W S .4140.0.4 .S T /1 ` I I Fwl+7Ji, W--T77'Tit - Ol1--0•Y-e'Yf� i;''ti Y=z��•.1 -_ -..1NL S w EX INLET] / 36[te STUB RIM J75U,62 O Scale/n Peet Fl m tSR)•171 1 0 ,-C•elC PED[SrAL FL our(N) =47s6;_ I mr 100 O I„�0 c0T To F.L.ir;(EE}.q49, \ pOyl(p Onx FL IfJ(VI)-.;45.?2 _ -, a 1019A E L LECT111 RIC POSEMETE WHfIRS T 1 la M 30 0 JO I [x 9 F.1 toll9 State /n Metere n:�.x O F-L OUT ;]�J 9? Contof47'/ntervatx: I FRat 1"-i1 ' ••••- DRAINAGE MAP CI,O SCALE:1-=100'i !Baas Datic 1/22/15 DA1 #14624 DRAINAGE AREA # 1 Contributing Area C Area (11'2) C * Area Composite ROW ROW 0.7375 52113 38433 ((0.95*43)+(0.2*17))/60 OS/Park 0.2 9100 1820 0.7375 Lots 0.35 113357 39675 Total 174570 79928.3 C = Weighted C Factor 0.46 A=Area(acres) 4.01 Required Gutter/Pipe Capacity (25-yr Storm) Tc Overland Flow Tc= 1.87 (1.1-CCf)D1/2/S1/3 Storm S = Slope of Basin(%) 0.5 Return Cf C =Rational Method Runoff Coefficient U..35 2 to 10 1 Cf= Frequency Adjustment Factor '1.1 11 to 25 1.1 D =Length of Basin(ft) 114 26 to 50 1.2 51 to 100 1.25 Tc Overland Flow(minutes) = 17.99 Tc Gutter Flow Tc= L/V/60 V = (1.486/n)R2/3 S1/2 n=Mannings Coefficient 0.013 R=Hydraulic Radius A/P (ft) 0.11 (0.15' below top of curb) S = slope (ft/ft) 0.009 L= length of gutter (ft) 838 V =mean velocity(ft/s) 2.84 Tc Gutter Flow(minutes) = 4.91 Tc Total (Overland + Gutter)= 22.90. Q = CIA C = Weighted C Factor 046 (calculated above) I= 0.78 Tc o.64(in/hr) 1.44 Drainage Area#1 A = area (acres) 4.01 Qrequired (CfS) = 2.65 Provided Gutter Capacity (flowing at 0.15' below top of curb) Q = (1.486/n)AR"'S" n=Mannings Coefficient 0.013 A = area(fe) 1.24 P =wetted perimeter (ft) 9.23 R=Hydraulic Radius AT (ft) 0.13 S = slope (ft/ft) 0.009 Qprovided (CfS) = 3.53 GUTTER HASADEQUATE CAPACITY Drainage Area#1 DRAINAGE AREA # 2 Contributing Area C Area(ft 2) C * Area Composite ROW ROW 0.7375 67847 50037 ((0.95*43)+(0.2*17))/60 OS/Park 0.2 3000 600 0.7375 Lots 0.35 104251 36488 Total 175098 87125 C = Weighted C Factor 0.50 A=Area(acres) 4.02 Required Gutter/Pipe Capacity (25-yr Storm) Tc Overland Flow Tc = 1.87 (1.1-CC)D1/2/S1/3 Storm S = Slope of Basin (%) 0.5 Return Cf C =Rational Method Runoff Coefficient 0.35 2 to 10 1 Cf= Frequency Adjustment Factor L l 11 to 25 1.1 D =Length of Basin (ft) 114 26 to 50 1.2 51 to 100 1.25 Tc Overland Flow(minutes) = 17.99 Tc Gutter Flow (West on Babcock) Tc=L/V/60 V = (1.486/n)R2i3 S11 n=Mannings Coefficient 0.013 R=Hydraulic Radius A/P (ft) 0.13 (0.15'below top of curb) S = slope (ft/ft) 0.006 L=length of gutter (ft) 1061 V =mean velocity(ft/s) 2.32 Tc Gutter Flow(minutes)= 7.61 Tc Total (Overland+ Gutter) Q = CIA C = Weighted C Factor t �R '' g �:,.:�Q.�O'�(calculated above) I = 0.78 Tc a64(in/hr) � )(: Drainage Area#2 A = area (acres) 4.02 Qrequired (CfS) = 2.69 Provided Gutter Capacity (flowing at 0.15' below top of curb) Q = (1.486/n)AR2i3SiI n= Mannings Coefficient 0.013 A= area(ft) 1.24 P =wetted perimeter (ft) 9.23 R= Hydraulic Radius AT (ft) 0.13 S = slope (ft/ft) 0.006 Qprovided (efS) = 2.88 GUTTER HAS ADEQUATE CAPACITY Drainage Area#2 DRAINAGE AREA 4 3 Contributing Area C Area(ft 2) C * Area Composite ROW ROW 0.7375 13319 9823 ((0.95*43)+(0.2*17))/60 OS/Park 0.2 0 0 0.7375 Lots 0.35 0 0 Total 13319 9822.76 C = Weighted C Factor 0.74 A=Area(acres) 0.34. Required Gutter/Pine Capacity (25-yr Storm) Tc Overland Flow Tc= 1.87 (1.1-CC)D1/2/S1/3 Storm S = Slope of Basin(%) 0.5 Return Cr C =Rational Method Runoff Coefficient 0.35 2 to 10 1 Cf=Frequency Adjustment Factor 11 11 to 25 1.1 D = Length of Basin (ft) 0 26 to 50 1.2 51 to 100 1.25 Tc Overland Flow(minutes) = 0400 Tc Gutter Flow (West on Babcock) Tc =LN/60 V = (1.486/n)R2' S" n= Mannings Coefficient 0.013 R=Hydraulic Radius A/P (ft) 0.13 (0.15'below top of curb) S = slope (ft/ft) 0.006 L= length of gutter(ft) 182 V =mean velocity(ft/s) 2.32 Tc Gutter Flow(minutes) Tc Total (Overland+ Gutter) Q = CIA C = Weighted C Factor 0.74 (calculated above) I= 0.78 TC 0.64(in/hr) 9.03 Drainage Area#3 A = area (acres) 0.31 Qrequired (CfS) = 2.04 Provided Gutter Capacity (flowing at 0.15' below top of curb) Q = (1.486/n)AR2/1SIi2 n=Mannings Coefficient 0.013 A = area(ft) 1.24 P =wetted perimeter(ft) 9.23 R= Hydraulic Radius A/P (ft) 0.13 S = slope (ft/ft) 0.006 Qprovided WS) = 2•88 GUTTER HASADEQUATE CAPACITY Drainage Area#3 DRAINAGE AREA # 4 Contributing Area C Area(11'�) C * Area Composite ROW ROW 0.7375 26062 19221 ((0.95*43)+(0.2*17))/60 OS/Park 0.2 6194 1239 0.7375 Lots (Dense Residential) 0.5 84657 42329 Lots 0.35 0 0 Total 116913 62788 C = Weighted C Factor 0.54 A=Area(acres) 2.68 Required Gutter/Pipe Capacity (25-yr Storm) Tc Overland Flow Tc = 1.87 (1.1-CC)D"/S1/3 Storm S = Slope of Basin (%) 0.5 Return Cr C = Rational Method Runoff Coefficient 0.5 2 to 10 1 Cf=Frequency Adjustment Factor 1:1 11 to 25 1.1 D = Length of Basin (ft) 205 26 to 50 1.2 51 to 100 1.25 Tc Overland Flow(minutes) Tc Gutter Flow (West on Babcock) Tc = L/V/60 V = (1.486/n)RZ/' S1i2 n=Mannings Coefficient 0 '3 R=Hydraulic Radius A/P (ft) =' '.0- 3, (0.15' below top of curb) S = slope (ft/ft) 0.012 L= length of gutter (ft) 474 V =mean velocity (ft/s) ;: 1=4' Tc Gutter Flow(minutes) Tc Total (Overland + Gutter) Q = CIA C = Weighted C Factor ; .. 0.54 (calculated above) Drainage Area#4 I = 0.78 Tc-0.64(in/hr) 1 .5 A = area (acres) 6 8 Qrequired (efs) = 2.20 Provided Gutter Capacity (flowinp, at 0.15' below top of curb) Q = (1.486/n)AR2"Sli2 n=Mannings Coefficient 0.013 A= area(ft) 1.24 P = wetted perimeter(ft) 9.23 R= Hydraulic Radius A/P (ft) 0.13 S = slope (ft/ft) 0.012 Qprovided (cfs) = 4.07 GUTTER HAS ADEQUATE CAPACITY Drainage Area#4 DRAINAGE AREA # 5 Contributing Area C Area(It') C * Area Composite ROW ROW 0.7375 43013 31722 ((0.95*43)+(0.2*17))/60 OS/Park 0.2 6000 1200 0.7375 Lots 0.35 86101 30135 Total 135114 63057.4 C = Weighted C Factor OA7. A=Area(acres) 3.10 0.47 Required Gutter/Pine Capacity (25-yr Storm) Tc Overland Flow Tc = 1.87 (1.1-CC)D1/2/S1/3 Storm S = Slope of Basin(%) 0.5 Return Cf C =Rational Method Runoff Coefficient q,35 2 to 10 1 Cf=Frequency Adjustment Factory 11 to 25 1.1 D =Length of Basin(ft) 114 26 to 50 1.2 51 to 100 1.25 Tc Overland Flow(minutes) = 17.99 Tc Gutter Flow (West on Babcock) Tc =L/V/60 V = (1.486/n)R2/3 S12 n=Mannings Coefficient 0.013 R= Hydraulic Radius A/P (ft) 0.1 ; (0.15'below top of curb) S = slope (ft/ft) 0.011 L= length of gutter (ft) 675 V =mean velocity (ft/s) 3.14 Tc Gutter Flow(minutes) 3.j 8 Tc Total (Overland + Gutter) _ 2.1.56 Q = CIA C = Weighted C Factor r(calculated above) I= 0.78 Tc o.64(in/hr) Drainage Area#5 A = area (acres) 3.10 `[required (CfS) = 2.17 Provided Cutter Capacity (flowing at 0.15' below top of curb) Q = (1.486/n)AR21S11 n= Mannings Coefficient 0.013 A = area(ft 2) 1.24 P =wetted perimeter (ft) 9.23 R= Hydraulic Radius A/P (ft) 0.13 S = slope (ft/ft) 0.011 QProvided (CfS) = 3.90 GUTTER HASADEQUATE CAPACITY Drainage Area#5 DRAINAGE AREA 9 6 Contributing Area C Area(ft) C * Area Composite ROW ROW 0.7375 26419 194'84 ((0.95*43)+(0.2*17))/60 OS/Park 0.2 4294 859 0.7375 Lots 0.35 60876 21307 Total 91589 41649.4 C = Weighted C Factor O A A = Area(acres) ?.10 Required Gutter/Pine Capacity (25-yr Storm) Tc Overland Flow Tc= 1.87 (1.1-CC)D1/2/S1/3 Storm S = Slope of Basin (%) 0.5 Return Cr C =Rational Method Runoff Coefficient 0:35 2 to 10 1 Cf= Frequency Adjustment Factor 1.1 11 to 25 1.1 D =Length of Basin (ft) 158 26 to 50 1.2 51 to 100 1.25 Tc Overland Flow(minutes) Tc Gutter Flow (West on Babcock) Tc= L/V/60 V = (1.486/n)R2/3 Sl/2 n=Mannings Coefficient O.: il R= Hydraulic Radius A/P (ft) 1.,t (0.15' below top of curb) S = slope (ft/ft) 0.013 L= length of gutter (ft) 556 V =mean velocity (ft/s) ,: Tc Gutter Flow(minutes) Tc Total (Overland + Gutter) Q = CIA C = Weighted C Factor (calculated above) I = 0.78 Tc-0*64(in/hr) Drainage Area#6 A = area(acres) 2.10 Qrequired (Cfs) = 1.34 Provided Gutter Capacity (flowing at 0.15' below top of curb) Q = (1.486/n)AR2"S" n= Mannings Coefficient 0.013 A= area(ft) 1.24 P = wetted perimeter (ft) 9.23 R= Hydraulic Radius A/P (ft) 0.13 S = slope (ft/ft) 0.013 Qprovided WS) = 4.24 GUTTER HAS ADEQUATE CAPACITY Drainage Area#6 DRAINAGE AREA # 7 Contributing Area C Area (ft 2) C * Area Composite ROW (Oak Street) South Side of Oak 0.75 22552 16914 ((0.95*22)+(0.2*8))/30 ROW (33' Street Width) 0.7375 8535 6295. 0.75 North Side Oak 0.95 11825 11234 Lots 0.35 22203 7771' Lots (Dense Residential) 0.5 31150 15575' Composite ROW (33' Street Width) Total 96265 57788.4 ((0.95*43)+(0.2*17))/60 0.7375 C = Weighted C Factor 0' A =Area (acres) !. Required Gutter/Pipe Capacity (25-yr Storm) Tc Overland Flow Tc= 1.87 (1.1-CCf)D1/2/S1/3 Storm S = Slope of Basin (%) 0.5 Return Cr C =Rational Method Runoff Coefficient 5 2 to 10 1 Cf= Frequency Adjustment Factor „� I�+ 11 to 25 1.1 D =Length of Basin (ft) 212 26 to 50 1.2 51 to 100 1.25 Tc Overland Flow(minutes) = 18 Tc Gutter Flow (West on Babcock) Tc=L/V/60 V = (1.486/n)R2/3 S1/2 n=Mannings Coefficient 0.013` R=Hydraulic Radius A/P (ft) 0.13 (0.15'below top of curb) S = slope (ft/ft) 0.012 L= length of gutter(ft) 243 V =mean velocity(ft/s) 3.28 Tc Gutter Flow (minutes) _ Tc Total (Overland + Gutter) _ Q = CIA Drainage Area# 7 C Weighted C Factor 0.60 (calculated above) I = 0.78 Tc-0.64(in/hr) 1.57 A = area (acres) 2.21, i Qrequired (CfS) = 2.W$ Provided Gutter Capacity (flowinIz at 0.15' below top of curb) Q = (1.486/n)AR"S" n=Mannings Coefficient 0.013 A= area(fe) 1.24 P =wetted perimeter(ft) 9.23 R= Hydraulic Radius A/P (ft) 0.13 S = slope (ft/ft) 0.012 Qprovided WS) = 4.07 GUTTER HAS ADEQUATE CAPACITY Drainage Area#7 DRAINAGE AREA # 8 Contributing Area C Area(ft 2) C * Area Composite ROW (Oak Street) Oak Street 0.675 25052 M910 ((0.95*28)+(0.2*32))/60 Laurel 0.72 63396 45645 0.675 Block 34 0.5 69209 34605 Lots 0.35 10734 3757 Total 16 8,;y1 100917 C = Weighted C Factor A= Area (acres) Required Gutter/Pipe Capacity (25-yr Storm) Tc Overland Flow Te = 1.87 (1.1-CCf)D1/2/S1/3 Storm S = Slope of Basin(%) 0.5 Return Cf C = Rational Method Runoff Coefficient 0.5 2 to 10 1 Cf= Frequency Adjustment Factor 1.1 11 to 25 1.1 D =Length of Basin(ft) 159 26 to 50 1.2 51 to 100 1.25 Tc Overland Flow(minutes) _ 0 Tc Gutter Flow (West on Babcock) Te= LN/60 V = (1.486/n)R2' Sv2 n= Mannings Coefficient 0.013 R=Hydraulic Radius A/P (ft) 0.1 3 (0.15' below top of curb) S = slope (ft/ft) 0.011 L= length of gutter(ft) 917 V =mean velocity (ft/s) 3.14, Te Gutter Flow(minutes) = 4.86, Tc Total (Overland + Gutter) Q = CIA C = Weighted C Factor (calculated above) Drainage Area#8 I= 0.78 Tc-0.64(in/hr) 1.52 A = area (acres) 3.87 Qrequired (CfS) = 3.52 Provided Gutter Capacity (flowing, at 0.15' below top of curb) Q = (1.486/n)AR2/3Sv2 n= Mannings Coefficient 0.013 A= area(ft 2) 1.24 P =wetted perimeter (ft) 9.23 R=Hydraulic Radius A/P (ft) 0.13 S = slope (ft/ft) 0.011 Qprovided (CfS) = 3.90 GUTTER HAS ADEQUATE CAPACITY Drainage Area#8 DRAINAGE AREA # 9 Contributing Area C Area (ft 2) C * Area Composite ROW ROW 0.7375 0 0 ((0.95*43)+(0.2*17))/60 OS/Park 0.2 5539 1108 0.7375 Lots(Dense Residential) 0.5 101653 50827 Total 107192 51934.3 C = Weighted C Factor 0.48 A = Area (acres) 2.46 Required Gutter/Pipe Capacity (25-yr Storm) Tc Overland Flow Tc = 1.87 (1.1-CC)D1/2/S1/3 Storm S = Slope of Basin (%) 0.5 Return Cf C = Rational Method Runoff Coefficient1Q, y 2 to 10 1 Cf=Frequency Adjustment Factor >?+,t 11 to 25 1.1 D =Length of Basin(ft) 557 26 to 50 1.2 51 to 100 1.25 Tc Overland Flow(minutes) _ ._ . Tc Gutter Flow (West on Babcock) Tc=L/V/60 V = (1.486/n)R2/3 Sv2 n=Mannings Coefficient 0.013 R=Hydraulic Radius A/P (ft) 0.1 3 (0.15'below top of curb) S = slope (ft/ft) 0.005 L= length of gutter (ft) 0 V =mean velocity (ft/s) 2.12 Tc Gutter Flow(minutes) = 0.00 Tc Total (Overland+ Gutter) _ J.,76 Q = CIA C = Weighted C Factor 0.4 8 (calculated above) I= 0.78 Tc 0.64(in/hr) 1.02 Drainage Area#9 A area (acres) 2.46 Q (cfs) = 1.21 Drainage Area#9 DRAINAGE AREA # 34E Contributing Area C Area(ft 2) C * Area Composite ROW Lots(Dense Residential) 0.5 86961 43481 Total 86961 43480.5 C = Weighted C Factor 0.50 A = Area(acres) 2.0.0 Required Gutter/Pipe Capacity (25-yr Storm) Tc Overland Flow Tc = 1.87 (1.1-CCf)D1/2/S1/3 Storm S = Slope of Basin (%) 0.5 Return Cr C = Rational Method Runoff Coefficient 035 2 to 10 1 Cf=Frequency Adjustment Factor 4:3 11 to 25 1.1 D =Length of Basin (ft) 662 26 to 50 1.2 51 to 100 1.25 Tc Overland Flow(minutes) _ 43,34 Tc Gutter Flow (West on Babcock) Tc =L/V/60 V = (1.486/n)R2/1 Sv2 n = Mannings Coefficient 0.013 R= Hydraulic Radius A/P (ft) 0,1; (0.15' below top of curb) S = slope (ft/ft) 0.005 L= length of gutter (ft) 0 V =mean velocity(ft/s) 2.12 Tc Gutter Flow(minutes) = 40 Tc Total (Overland+ Gutter) = t>o11 Q = CIA C = Weighted C Factor 1 (calculated above) I= 0.78 Tc o.ba(in/hr) A = area(acres) Drainage Area#34E Q (cfs) = 0.96 Drainage Area#34E §Qy}1} S�MH 1/�_Ic SCI14�5 stv.<D ,♦ l J'J / / , /♦ /st_I�sso+nll: J , , , J / l i ;J /i // i / J /�J,/.' iv"LET Al '/, // /''/%fp,M�bfDUA_:N; ;SCVHi ' : /SOVNlm�' % ' /•'' !/' /' �siOAu unfit �'/ ' ' / J'..:/�'''' /, /'/' �J,J / '/''� /' ,j/� i � �'A7� ♦57/ORu 1M/Et''.':�J'/ /J/ ,J''/',//i/'Ii'J/ /'',� ',/Ji // / /t1CRtI11afT i 31 3 4� §iCRV M'LET i / ' ♦ ' / ,''/ / '''/�,', ♦§POKY uSET W • � J /// I/ J.� / , /' ''/ /' / '/ J/J 'JJ J / I / Project Description File Name............................................................................. 14624-BOULDER CREEK PROPOSED.SPF Description............................................................................ G:\c&h\14\14624\STORMWATER\OVERALL DRAINAGE AREAS.dwg rroject Options FlowUnits.............................................................................CFS Elevation Type...................................................................... Elevation Hydrology Method..........................................._. . _ Rational Time of Concentration(TOC)Method................................. User-Defined Link Routing Method...........................................................Hydrodynamic Enable Overflow Ponding at Nodes............... I YES Skip Steady State Analysis Time Periods......................... NO Analysis Options Start Analysis On.................................................................. Feb 26,2015 00:00:00 End Analysis On................................................................... Feb 27,2015 00:00:00 Start Reporting On................................................................Feb 26,2015 00:00:00 Antecedent Dry Days............................................................0 days Runoff(Dry Weather)Time Step..........................................0 01:00:00 days hh:mm:ss Runoff(Wet Weather)Time Step........................................ 0 00:05:00 days hh:mm:ss Reporting Time Step............................................................ 0 00:05:00 days hh:mm:ss Routing Time Step................................................................30 seconds Number of Elements Qty RainGages...........................................................................0 Su b b a s i n s..............................................................................8 Nodes.................................................................................... 19 Junctions...................................................................... 7 Outialls......................................................................... 4 Flow Diversions........................................................... 0 Inlets............................................................................ 8 StorageNodes............................................................. 0 Links...................................................................................... 17 Channels...................................................................... 2 Pipes............................................................................ 15 Pumps.......................................................................... 0 Orifices......................................................................... 0 Weirs....................»...................................................... 0 Outlets.......................................................................... 0 Pollutants.............................................................................. 0 LandUses............................................................................ 0 Rainfall Details Return Period........................................................................ 25 year(s) Subbasin Summary SN Subbasin Area Weighted Total Total Total Peak Time of ID Runoff Rainfall Runoff Runoff Runoff Concentration Coefficient Volume (ac) (in) (in) (ac-in) (cfs) (days hh:mm:ss) 1 (Drainage Areas).DA 1 4.01 0.4600 0.55 0.25 1.01 2.67 0 00:22:54 2(Drainage Areas).DA 2 4.02 0.5000 0.58 0.29 1.16 2.70 0 00:25:36 3(Drainage Areas).DA 3 0.31 0.7400 0.20 0.15 0.05 2.07 0 00:01:18 4(Drainage Areas).DA 4 2.68 0.5400 0.54 0.29 0.77 2.21 0 00:20:57 5{Drainage Areas).DA 5 3.10 0.4700 0.54 0.25 0.78 2.19 0 00:21:33 6{Drainage Areas}.DA 6 2.10 0.4500 0.56 0.25 0.53 1.33 0 00:23:53 7{Drainage Areas}.DA 7 2.21 0.6000 0.53 0.32 0.70 2.08 0 00:20:06 8{Drainage Areas).DA 8 2.48 0.6700 0.54 0.36 0.89 2.52 0 00:21:12 Node Summary SN Element Element Invert Ground/Rim Initial Surcharge Ponded Peak Max HGL Max Min Time of Total Total Time ID Type Elevation (Max) Water Elevation Area Inflow Elevation Surcharge Freeboard Peak Flooded Flooded Elevation Elevation Attained Depth Attained Flooding Volume Attained Occurrence 01) (ft) (ft) (ft) (It) (cfs) ((t) (ft) (ft) (days hh mm) ac in) (min) 1 SDMH 10 Junction 4734.50 4738.14 4734.50 4738.14 0.00 2.92 4735.28 0.00 2.86 0 00:00 0.00 000 2 SDMH 4 Junction 4737.22 4740.76 4737.22 4740.76 0.00 1.67 4737.60 0.00 3.16 0 00:00 0.00 0.00 3 SDMH 5 Junction 4740.69 4744.13 4740.69 4744.14 0.00 1.68 4741.11 0.00 3.02 0 00:00 0.00 0.00 4 SDMH 6 Junction 4742.03 4746.14 4742.03 4746.14 0.00 1.69 4742.49 0.00 3.65 0 00:00 0.00 0.00 5 SDMH 9 Junction 4733.23 4737.70 4733.23 4737.70 0.00 2.92 4733.79 0.00 3.91 0 00:00 0.00 0.00 6 SDMH 7 Junction 4733.52 4736.31 4733.52 4736.31 0.00 2.52 4734.22 0.00 2.09 0 00:00 0.00 0.00 7 SDMH 8 Junction 4732.87 4737.37 4732.87 4737.37 0.00 2.51 4733.56 0.00 3.81 0 00:00 0.00 0.00 8 Pond-5(1) Outfall 4731.80 2.91 4732.29 9 Pond_5(2) Outfall 4732.69 6.11 4733.346 10 Pond_ Outfall 4739.21 3.36 4739.95 11 Pond 8 Outfall 4732.57 2.50 4733.15 Link Summary "N Element Element From To(Outlet) Length Inlet Outlet Average Diameter or Manning's Peak Design Flow Peak Flow/ Peak Flow Peak Flow Peak Flow Total Time Reported ID Type (Inlet) Node Invert Invert Slope Height Roughness Flow Capacity Design Flow Velocity Depth Depth/Surcharged Condition Node Elevation Elevation Ratio Total Depth Ratio (R) (ft) (0) N (in) (cfs) (cfs) (fUsec) (0) (min) 1 SDMH 10 to SDMH_9 Pipe SDMH 10 SDMH 9 251.00 4734.50 4733.23 0.5100 15.000 0.0130 2.92 4.59 064 4.38 0.67 0,53 0.00 Calculated 2 SDMH_4S to I 5 Pipe SDMH 4 STORM INLET 5 75.00 4737.22 4735.84 1.8400 15.000 0.0130 1.67 8.76 019 3.56 0.51 0.41 0.00 Calculated 3 SDMH-6-to-SDMH-5 Pipe SDMH 6 SDMH 5 131.00 4742.03 4740.69 1.0200 15.000 0.0130 1.68 6.53 0 26 4.33 0.44 0.35 0.00 Calculated 4 SDMH 7 to SI 2 Pipe STORMINLET_2 SDMH 7 17.00 4733.67 4733.52 0.9100 15.000 0.0130 2.52 6.15 041 3.32 0.74 059 0.00 Calculated 5SDMH 8 to_Pontl_8 Pipe SDMH_8 Pond 8 38.00 4732.87 4732.57 0.7900 15.000 0.0130 2.50 5.74 044 4.01 0.63 051 0.00 Calculated 6SDMH 8 to SDMH 7 Pipe SDMH_7 SDMH 8 107.00 4733.52 4732.87 0.6100 15.000 0.0130 2.51 5.03 050 3.60 0.69 055 0.00 Calculated 7 SDMH_9 to Pond-5 Pipe SDMH 9 Pond_50) 75.00 4733.23 4731.80 1.9100 15.000 0.0130 2.91 8.92 0.33 5.96 0.52 0A2 0.00 Calculated 8 SDMHS to SDMH4 Pipe SDMH 5 SDMH 4 266,00 4740.69 4737.22 1.3000 15.000 0.0130 1.67 7.38 023 4.90 0.40 0.32 0.00 Calculated 9 SI 1 to SDMH10 Pipe STORM INLET 1 SDMH 10 32.00 4734.75 4734.50 0.7800 15.000 0.0130 2.92 5.71 0 51 3.49 0.81 0.65 0.00 Calculated 10 SI 10 to SI 9 Pipe STORM INLET 10 STORM INLET 9 26.00 4740.20 4739.40 3.0800 15.000 0.0130 3.36 11.33 0.30 4.12 0.79 0.63 0.00 Calculated 11 SI_3 to Pond Pipe STORM INLET 3 Pond_5(2) 74.00 4734.38 4732.69 2.2800 18.000 0.0130 6.11 15.87 0.39 7.46 0.71 047 0.00 Calculated 12 SW to to SI 3 Pipe STORM INLET 4 STORM INLET 3 53.00 4734.67 4734.38 0.5500 18.000 0.0130 4.87 7.77 0 63 4.48 0.89 059 0.00 Calculated 13 SI5 to SI 4 Pipe STORM INLET 5 STORM INLET 4 233.00 4735.84 4734.67 0.5000 18.000 0.0130 2.77 7.44 037 2.84 0.82 0.55 0.00 Calculated 14 SI_6 to SDMH 6 Pipe STORM INLET 6 SDMH 6 37.00 4742.32 4742.03 0.7800 15.000 0.0130 1.69 5.72 029 3.65 0.50 040 0.00 Calculated 15 SI 9 to Pond Pipe STORM_INLET 9 Pond-6 35.00 4739.40 4739.21 0.5300 15.000 0.0130 3.36 4.70 0.72 3.80 0.85 0.68 0.00 Calculated 16 Gutter 1 Channel STORM INLET 5 STORM INLET 1 260.00 4739.66 4737.70 0.7500 6.120 0.0320 0.99 13.03 0.08 1.84 0.25 0.48 0.00 17 Gutter-2 Channel STORM INLET 6 STORM INLET 10 485.00 4746.34 4743.69 0.5500 6.120 0.0320 0.98 11.09 009 1.13 026 0.51 0.00 Inlet Summary SN Element Inlet Manufacturer Inlet Number of Catchbasin Max(Rim) Initial Ponded Peak Peak Flow Peak Flow Inlet Allowable Max Gutter Max Gutter ID Manufacturer Part Location Inlets Invert Elevation Water Area Flow Intercepted Bypassing Efficiency Spread Spread Water Elev. Number Elevation Elevation by Inlet during Peak during Peak during Peak Inlet Flow Flow Flow (8) (4) A W) (cfs) (cfs) (cfs) N (0) (ft) (ft) 1 STORM INLET 1 NEENAH FOUNDRY R-3067-L On Sag 1 4734.75 4737.70 4734.75 10.00 3.00 NIA NIA NIA 9.00 7.92 4737.98 2 STORM INLET 3 NEENAH FOUNDRY R-3067-L On Sag 1 4734.38 4737.66 4734.38 10.00 1.33 NIA NIA NIA 9.00 3.89 4737.83 3 STORM INLET 4 NEENAH FOUNDRY R-3067-L On Sag 1 4734.67 4738.04 4734.67 10.00 2.19 NIA NIA NIA 9.00 6.09 4738.27 4 STORM INLET 5 NEENAH FOUNDRY R 3067 L Type L On Grade 1 4735.84 4739.66 4735.84 NIA 2.21 1.21 1.00 54.88 9.00 5.68 4739.88 5 STORM INLET 6 NEENAH FOUNDRY R 3067 L Type L On Grade 1 4742.32 4746.34 4742.32 NIA 2.66 1.69 0.98 63.33 9.00 7.30 4746.61 6 STORM INLET 2 NEENAH FOUNDRY R-3067-L On Sag 1 4733.67 4736.39 4733.67 10.00 2.52 NIA NIA NIA 9.00 6.87 4736.65 7 STORM INLET 10 NEENAH FOUNDRY R-3067-L On Sag 1 4740.20 4743.69 4740.20 10.00 3.49 NIA NIA NIA 9.00 8.93 4744.00 8 STORM-INLET 9 NEENAH FOUNDRY R-3067-L On Sag 1 4739.40 4743.69 4739.40 10.00 2.05 NIA NIA NIA 9.00 5.76 4743.91 Junction Input SN Element Invert Ground/Rim Ground/Rim Initial Initial Surcharge Surcharge Ponded Minimum ID Elevation (Max) (Max) Water Water Elevation Depth Area Pipe Elevation Offset Elevation Depth Cover (ft) (ft) (ft) (ft) (it) (ft) L4f_ !fl'1 (in) 1 SDMH 10 4734.50 4738.14 3.64 4734.50 0.00 4738.14 0.00 000 0.00 2 SDMH 4 4737.22 4740.76 3.54 4737.22 0.00 4740.76 0.00 0.00 0.00 3 SDMH 5 4740.69 4744.13 3.44 4740.69 0.00 4744.14 0.01 0.00 0.00 4 SDMH 6 4742.03 4746.14 4.11 4742.03 0.00 4746.14 0.00 0.00 0.00 5 SDMH 9 4733.23 4737.70 4.47 4733.23 0.00 4737.70 0.00 0.00 0.00 6 SDMH 7 4733.52 4736.31 2.79 4733.52 0.00 4736.31 0.00 0.00 0.00 7 SDMH 8 4732.87 4737.37 4.50 4732.87 0.00 4737.37 0.00 0.00 0.00 Junction Results SN Element Peak Peak Max HGL Max HGL Max Min Average HGL Average HGL Time of Time of Total Total Time ID Inflow Lateral Elevation Depth Surcharge Freeboard Elevation Depth Max HGL Peak Flooded Flooded Inflow Attained Attained Depth Attained Attained Attained Occurrence Flooding Volume Attained Occurrence (cfs) (cfs) (ft) (ft) (ft) (ft) (ft) (ft) (days hh:mm) (days hh:mm) (ac-in) (min) 1 SDMH 10 2.92 0.00 4735.28 0.78 0.00 2.86 4734.57 0.07 0 00:22 0 00:00 0.00 0.00 2 SDMH 4 1.67 0.00 4737.60 0.38 0.00 3.16 4737.26 0.04 0 00:24 0 00:00 0.00 0.00 3 SDMH 5 1.68 0.00 4741.11 0.42 0.00 3.02 4740.73 0.04 0 00:23 0 00:00 0.00 0.00 4 SDMH 6 1.69 0.00 4742.49 0.46 0.00 3.65 4742.08 0.05 0 00:23 0 00:00 0.00 0.00 5 SDMH 9 2.92 0.00 4733.79 0.56 0.00 3.91 4733.28 0.05 0 00:22 0 00:00 0.00 0.00 6 SDMH 7 2.52 0.00 4734.22 0.70 0.00 209 4733.58 0.06 0 00:21 0 00:00 0.00 0.00 7 SDMH 8 2.51 0.00 4733.56 0.69 0.00 3.81 4732.93 0.06 0 00:21 0 00:00 0.00 0.00 Channel Input SN Element Length Inlet Inlet Outlet Outlet Total Average Shape Height Width Manning's Entrance Exit/Bend Additional Initial Flap ID Invert Invert Invert Invert Drop Slope Roughness Losses Losses Losses Flow Gate Elevation Offset Elevation Offset (ft) (ft) (ft) (ft) (ft) (ft) (%) (ft) (ft) (cfs) 1 Gufter_1 260.00 4739.66 3.82 4737.70 2.95 1.96 0.7500 User-Defined 0.510 16.500 0.0320 0.5000 0.5000 0.0000 0.00 No 2 Gutter-2 485.00 4746.34 4.02 4743.69 3.49 2.65 0.5500 User-Defined 0.510 16.500 0.0320 0.5000 0.5000 0.0000 0.00 No Channel Results SN Element Peak Time of Design Flow Peak Flow/ Peak Flow Travel Peak Flow Peak Flow Total Time Froude Reported ID Flow Peak Flow Capacity Design Flow Velocity Time Depth Depth/ Surcharged Number Condition Occurrence Ratio Total Depth Ratio (cfs) (days hh:mm) (cis) (ft/sec) (min) (R) (min) 1 Gutler_1 0.99 0 00:21 13.03 0.08 1.84 2.36 0.25 0.48 0.00 2 Gutter 2 0.98 0 00:23 11.09 0.09 1.13 7.15 0.26 0.51 0.00 Pipe Input SN Element Length Inlet Inlet Outlet Outlel Total Average Pipe Pipe Pipe Manning's Entrance Exit/Bend Additional Initial ID Invert Invert Invert Invert Drop Slope Shape Diameteror Width Roughness Losses Losses Losses Flow Elevation Offset Elevation Offset Height (ft) (ft) (ft) (ft) (ft) (ft) (%) (in) (in) (cfs) 1 SDMH_10 to_SDMH_9 251.00 4734.50 0.00 4733.23 0.00 1.27 0.5100 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 2 SDMH4to SI_5 75.00 4737.22 0.00 4735.84 0.00 1.38 1.8400 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 3 SDMH__6__to_SDMH_5 131.00 4742.03 0.00 4740.69 0.00 1.34 1.0200 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 4 SDMH_7_to_SI_2 17.00 4733.67 0.00 4733.52 0.00 0.15 0.9100 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 5 SDMH8 to Pond 8 38.00 4732.87 0.00 4732.57 0.00 0.30 0.7900 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 6 SDMH_8^to_SDMH 7 107.00 4733.52 0.00 4732.87 0.00 0.65 0.6100 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 7 SDMH_9_-to_Pond 5 75.00 4733.23 0.00 4731.80 0.00 1.43 1.9100 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 8 SDMH5 to_SDMH4 266.00 4740.69 0.00 4737.22 0.00 3.47 1.3000 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 9 SI_1_to_^SDMH10 32.00 4734.75 0.00 4734.50 0.00 0.25 0.7800 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 10 SI_10_to_SI_9 26.00 4740.20 0.00 4739.40 0.00 0.80 3.0800 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 11 SI_3_to_Pond 74.00 4734.38 0.00 4732.69 0.00 1.69 2.2800 CIRCULAR 18.000 18.000 0.0130 0.5000 0.5000 0.0000 0.00 12 SI4toSI_3 53.00 4734.67 0.00 4734.38 0.00 0.29 0.5500 CIRCULAR 18.000 18.000 0.0130 0.5000 0.5000 0.0000 0.00 13 SI__57_to7_SI_4 233.00 4735.84 0.00 4734.67 0.00 1.17 0.5000 CIRCULAR 18.000 18.000 0.0130 0.5000 0.5000 0.0000 0.00 14 SI_6_to_SDMH_6 37.00 4742.32 0.00 4742.03 0.00 0.29 0.7800 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 15 SI 9 to Pond 35.00 4739.40 0.00 4739.21 0.00 0.19 0.5300 CIRCULAR 15.000 15.000 0.0130 0.5000 0.5000 0.0000 0.00 Flap No.of Gate Barrels • 1 No t No 1 No 1 No 1 No 1 No 1 No 1 No 1 No 1 No 1 No 1 No 1 No 1 No 1 Pipe Results SN Element Peak Time of Design Flow Peak Flow/ Peak Flow Travel Peak Flow Peak Flow Total Time Froude Reported ID Flow Peak Flow Capacity Design Flow Velocity Time Depth Depth/ Surcharged Number Condition Occurrence Ratio Total Depth Ratio (cfs) (days hh:mm) (cfs) (ft/sec) (min) (ft) (min) 1 SDMH_10_to_SDMH 9 2.92 0 00:22 4.59 0.64 4.38 0.96 0.67 0.53 0.00 Calculated _2 SDMH_4_toSI_5 _ 1.67 0 00:24 8.76 0.19 3.56 0.35 0.51 0.41 0.00 Calculated 3 SDMH_6_to_SDMH_5 1.68 0 00:23 6.53 0.26 4.33 0.50 0.44 0.35 0.00 Calculated 4 SDMH7_to_SI_2 2.52 0 00:21 6.15 0.41 3.32 0.09 0.74 0.59 0.00 Calculated M 5 SDH_6to_Pond_8 2.50 0 00:21 5.74 0.44 4.01 0.16 0.63 0.51 0.00 Calculated 6 SDMH_8 to_SDMH_7 251 0 00:21 5.03 0.50 3.60 0.50 0.69 0.55 0.00 Calculated 7 SDMH_9^_to_Pond_5 2.91 0 00:22 8.92 0.33 5.96 0.21 0.52 0.42 0.00 Calculated 8 SDMH5_to_SDMH4 1.67 0 00:23 7.38 0.23 4.90 0.90 0.40 0.32 0.00 Calculated 9 SI_1_to_SDMH10 2.92 0 00:21 5.71 0.51 3.49 0.15 0.81 0.65 0.00 Calculated 10 SI_10_to_SI_9 3.36 0 00:26 11.33 0.30 4.12 0.11 0.79 0.63 0.00 Calculated 11 SI_3_to_Pond 6.11 0 00:22 15.87 0.39 7.46 0.17 0.71 0.47 0.00 Calculated 12 SI_4 to_SI_3 4.87 0 00.22 7.77 0.63 4.48 0.20 0.89 0.59 0.00 Calculated 13 SI_5_to_SI_4 2.77 0 00:24 7.44 0.37 2.84 1.37 0.82 0.55 0.00 Calculated 14 SI_6_to_SDMF_6 1.69 0 00:23 5.72 0.29 3.65 0.17 0.50 0.40 0.00 Calculated 15 SI 9 to Pond 3.36 0 00:26 4.70 0.72 3.80 0.15 0.85 0.68 0.00 Calculated Inlet Input SIN Element Inlet Manufacturer Inlet Number of Catchbasin Max(Rim) Inlet Initial Initial Ponded Grate ID Manufacturer Part Location Inlets Invert Elevation Depth Water Water Area Clogging Number Elevation Elevation Depth Factor _ (o) (ft) (It) (11) (ft) ((N) (%) 1 STORM INLET 1 NEENAH FOUNDRY R-3067-L On Sag 14734.75 4737.70 2.95 4734.75 0.00 10.00 0.00 2 STORM INLET 3 NEENAH FOUNDRY R-3067-L On Sag 1 4734.38 4737.66 3.28 4734.38 0.00 10.00 0.00 3 STORM INLET 4 NEENAH FOUNDRY R-3067-L On Sag 1 4734.67 4738.04 3.37 4734.67 0.00 10.00 0.00 4 STORM INLET 5 NEENAH FOUNDRY R 3067 L Type L On Grade 1 4735.84 4739.66 3.82 4735.84 0.00 N/A 0.00 5 STORM INLET 6 NEENAH FOUNDRY R 3067 L Type L On Grade 1 4742.32 4746.34 4.02 4742.32 0.00 N/A 0.00 6 STORM INLET 2 NEENAH FOUNDRY R-3067-L On Sag 1 4733.67 4736.39 2.72 4733.67 0.00 10.00 0.00 7 STORM_INLET 10 NEENAH FOUNDRY R-3067-L On Sag 1 4740.20 4743.69 3.49 4740.20 0.00 10.00 000 8 STORM-INLET 9 NEENAH FOUNDRY R-3067-L On Sag 1 4739.40 4743.69 4.29 4739.40 0.00 10.00 0.00 Inlet Results SN Element Peak Peak Peak Flow Peak Flow Inlet Max Gutter Max Gutter Max Gutter Time of Total Total Time ID Flow Lateral Intercepted Bypassing Efficiency Spread Water Elev. Water Depth Max Depth Flooded Flooded Inflow by Inlet during Peak during Peak during Peak during Peak Occurrence Volume Inlet Flow Flow Flow Flow (cfs) (cfs) (cfs) (cfs) (%) (ft) (ft) ((t) (days hh,mm) (ao-in) (1»i11)_ 1 STORM INLET 1 3.00 2.08 N/A N/A N/A 7.92 4737.98 0.26 0 00:21 0.00 0.00 2 STORM INLET 3 1.33 1.33 N/A N/A N/A 3.89 4737.83 0.17 0 00:22 0.00 0.00 3 STORM INLET 4 2.19 2.19 N/A N/A N/A 6.09 4738.27 0.23 0 00:22 0.00 0.00 4 STORM INLET 5 2.21 2.21 1.21 1.00 54.88 5.68 4739.88 0.22 0 00:24 0.00 0.00 5 STORM INLET 6 2.66 2.66 1.69 0.98 63.33 7.30 4746.61 0.27 0 00:23 0.00 0.00 6 STORM INLET 2 2.52 2.52 N/A N/A N/A 687 4736.65 0.26 0 00:21 0.00 0.00 7 STORM INLET 10 349 2.70 N/A N/A N/A 8.93 4744.00 0.31 0 00:26 0.00 0.00 8 STORM INLET 9 2.05 2.05 N/A N/A N/A 5.76 4743.91 0.23 0 00:26 0.00 0.00 DETENTION POND # 5 REQUIRED VOLUME 2. Calculate Area and Weighted C Factor(Post-Development) Contributing Area C Area (ft2) C *Area Lot 2 0.35 22203 7771 Lot 3 0.5 31150 15575 Lot 4 0.5 26662 13331 Lot 6 0.35 33308 11658 Lot 7 0.35 19939 6979 Lot 8 0.35 16043 5615 Lot 9 0.35 27568 9649 Lot 10 0.35 22767 7968 Lot 11 0.35 27352 9573 Lot 12 0.35 57995 20298 Lot 17 0.35 30816 10786 Lot 18 0.35 32524 11383 Lot 20 0.35 24817 8686 Lot 21 0.35 25200 8820 Isabella Sherwood ROW 3 0.74 52113 38564 Sherwood Abigail ROW 7 0.74 26062 19286 Abigail Saxon ROW 8 0.74 21254 15728 Sherwood Samantha ROW 4 0.74 21759 16102 Samantha ROW 5 0.74 18442 13647 Saxon ROW 6 0.74 7977 5903 Oak ROW 9 0.74 22552 16688 Oak ROW 10 0.95 11825 11234 Abigail ROW 0.74 8535 6316 OS B 0.2 3000 600 OS C 0.2 3100 620 OS D 0.2 4294 859 OS E 0.2 3000 600 OS F 0.2 3000 600 OS G 0.2 6194 1239 Total 611451 296077 A =Area(acres) 14.0370 C = Weighted C Factor 0.48 3. Calculate T, (Pre-Development) Tc Overland Flow Tc= 1.87 (1.1-CCf)D1/2/Sli3 -------............----------------- Storm S = Slope of Basin (%) 1 :Return (yrs) Cf C = Rational Method Runoff Coefficient 0.2 !2 to 10 1 Cf= Frequency Adjustment Factor 1.1 :11 to 25 1.1; D = Length of Basin (ft) 1512 26 to 50 1.2 '51 to 1001 25- '•-------- -- _ ___ _ _ 6. Calculate Required Pond Volume Total Area (acres) = 14.04 acres Weighted C = 0.48 Discharge Rate (cfs) = 1.72 cfs (Equal to Pre-Development Runoff Rate) Duration(min) Duration(hrs) Intensity Q�� (cfs) Runoff Release Required (in/hr) Volume Volume Storage (ft3) 46 0.77 0.76 5.17 14270 4756 9514 47 0.78 0.75 5.10 14377 4859 9518 48 0.80 0.74 5.03 14484 4963 9521 49 0.82 0.73 4.96 14589 5066 9523 50 0.83 0.72 4.90 14692 5169 9523 51 0.85 0.71 4.83 14794 5273 9522 52 0.87 0.70 4.77 14895 5376 9519 53 0.88 0.69 4.72 14995 5480 9515 54 0.90 0.69 4.66 15093 5583 9510 55 0.92 0.68 4.60 15191 5686 9504 56 0.93 0.67 4.55 15287 5790 9497 57 0.95 0.66 4.50 15382 5893 9489 58 0.97 0.65 4.45 15476 5996 9479 59 0.98 0.65 4.40 15568 6100 9469 OUTLET STRUCTURE SLOT Q=CLH Q = Discharge (cfs) 1.72 C = Weir Coefficient 3.33 (per COB Design Standards) H = Head (ft) 1.5 L = Horizontal Length (ft) 0.28 L = Slot Width (inches) 3.4 Tc (Pre-Development) (minutes) 64 4. Calculate Rainfall Intensity(Duration =Pre-Development Tc) i = 0.64z o.65 (10-yr Storm, Fig. 1-3, COB Design Standards) x = storm duration (hrs) 1.07 (Tc Pre-Development) i= rainfall intensity(in.1hr.) 0.61 5. Calculate Runoff Rate(Pre-Development) Q = CiA C = Rational Method Runoff Coefficient 0.2 (open land) i = rainfall intensity(in./hr.) 0.61 (calculated above) A= Area (acres) 14.04 (calculated above) Q =Runoff Rate (Pre-Development) (cfs) 1.72 DETENTION POND #6 REQUIRED VOLUME 2. Calculate Area and Weighted C Factor(Post-Development) Contributing Area C Area (ft2) C *Area Lot 14 0.35 17989 6296 Lot15 0.35 30900 10815 Lot16 0.35 30816 10786 Lot 19 0.35 24816 8686 Sherwood ROW 1 0.74 13319 9856 Sherwood Abigail ROW 2 0.74 67847 50207 OS A 0.2 3000 600 Total 188687 97245 A =Area(acres) 4.3317 C = Weighted C Factor 0.52 3. Calculate T, (Pre-Development) Tc Overland Flow Tc= 1.87 (1.1-CCf)D'/2/S1/3 ------------------------------ Storm S = Slope of Basin (%) 1 'Return (yrs) Cf C = Rational Method Runoff Coefficient 0.2 12 to 10 1 Cf= Frequency Adjustment Factor 1.1 ;11 to 25 1.1 D = Length of Basin (ft) 1512 -26 to 50 1.2 51 to 100 1.25 Tc (Pre-Development) (minutes) 64 4. Calculate Rainfall Intensity(Duration = Pre-Development Tc) i = 0.64x o.65 (10-yr Storm, Fig. 1-3, COB Design Standards) x= storm duration (hrs) 1.07 (Tc Pre-Development) i=rainfall intensity(in.1hr.) 0.61 5. Calculate Runoff Rate(Pre-Development) Q = CiA C = Rational Method Runoff Coefficient 0.2 (open land) i = rainfall intensity (in./hr.) 0.61 (calculated above) A=Area (acres) 4.33 (calculated above) Q =Runoff Rate (Pre-Development) (cfs) 0.53 6. Calculate Required Pond Volume Total Area (acres) = 4.33 acres Weighted C = 0.52 Discharge Rate (cfs) = 0.53 cfs (Equal to Pre-Development Runoff Rate) Duration(min) Duration(hrs) Intensity Q�� (cfs) Runoff Release Required (in/hi) Volume Volume Storage (ft) 48 0.80 0.74 1.65 4157 1531 3226 49 0.82 0.73 1.63 4792 1563 3228 50 0.83 0.72 1.61 4826 1595 3230 51 0.85 0.71 1.59 4859 1627 3232 52 0.87 0.70 1.57 4892 1659 3233 53 0.88 0.69 1.55 4925 1691 3234 54 0.90 0.69 1.53 4957 1723 3234 55 0.92 0.68 1.51 4989 1755 3235 56 0.93 0.67 1.49 5021 1787 3234 57 0.95 0.66 1.48 5052 1819 3233 58 0.97 0.65 1.46 5083 1850 3232 OUTLET STRUCTURE SLOT Q=CLH"` Q = Discharge (cfs) 0.53 C = Weir Coefficient 3.33 (per COB Design Standards) H = Head (ft) 1.5 L = Horizontal Length (ft) 0.09 L = Slot Width (inches) 1.0 RETENTION POND #7 REQUIRED VOLUME 1. Calculate Area and Weighted C Factor Contrihutilig Area G Area (ft') C *Area Lot 5 0.5 49926 24963 OS H 0.2 5539 1108 Lot 13 0.5 51727 25864 Total 107192 51934 C=Weighted C Factor 0.48 3. Calculate Required Volume Q = CIA V=72000 C =Weighted C Factor 0.48 1 = intensity(in/hr) 0.41 (10 yr, 2hr storm) A= Area (acres) 2.46 Q = runoff(cfs) 0.49 V= REQUIRED VOL (ft) 3520 DETENTION POND #8 TO BE CONVERTED TO DETENTION REQUIRED VOLUME 2. Calculate Area and Weighted C Factor(Post-Development) _Contributing Area C Area (ft2) C *Area Block 34 East 0.5 86961 43481 Block 34 West 0.5 69209 34605 Oak Laurel ROW 14 0.72 63396 45645 Oak ROW 11 0.95 6025 5724 Oak ROW 12 0.74 12177 9011 Oak ROW 13 0.74 6850 5069 Lot 1 0.35 10734 3757 Total 255352 147291 A =Area(acres) 5.8621 C= Weighted C Factor 0.58 3. Calculate T, (Pre-Development) Tc Overland Flow Tc= 1.87 (1.1-CCf)D'12/S'/3 Storm S = Slope of Basin (%) 1.9 ;Return (yrs) Cf C = Rational Method Runoff Coefficient 0.2 :2 to 10 ill Cf= Frequency Adjustment Factor 1.1 ;11 to 25 1.1: D = Length of Basin (ft) 662 ;26 to 50 1.2; 51 to 100 1.25; .---------------_- Tc(Pre-Development) (minutes) 34 4. Calculate Rainfall Intensity(Duration =Pre-Development Tc) i = 0.64x o.65 (10-yr Storm, Fig. 1-3, COB Design Standards) x= storm duration (hrs) 0.57 (Tc Pre-Development) i=rainfall intensity(in./hr.) &92 5. Calculate Runoff Rate (Pre-Development) Q = CiA C = Rational Method Runoff Coefficient 0.2 (open land) i = rainfall intensity (in./hr.) 0.92 (calculated above) A= Area (acres) 5.86 (calculated above) Q =Runoff Rate (Pre-Development) (cfs) 1.08 6. Calculate Required Pond Volume Total Area (acres) = 5.86 acres Weighted C = 0.58 Discharge Rate (cfs) = 1.08 cfs (Equal to Pre-Development Runoff Rate) Duration(min) Duration(hrs) Intensity Q.� (cfs) Runoff Release Required3 (in/hr) Volume Volume Storage W) 48 0.80 0.74 2.50 7205 3115 4090 49 0.82 0.73 2.47 7257 3180 4078 50 0.83 0.72 2.44 7309 3245 4064 51 0.85 0.71 2.41 7360 3310 4050 52 0.87 0.70 2.38 7410 3375 4035 53 0.88 0.69 2.35 74.60 3439 4020 54 0.90 0.69 2.32 7509 3504 4004 55 0.92 0.68 2.29 7557 3569 3988 5.6 0.93 0.67 2.26 7605 3634 3971 57 0.95 0.66 2.24 7652 3699 3953 58 0.97 0:65 2.21 7699 3764 3935 OUTLET STRUCTURE SLOT Q=CLH '1 Q = Discharge (cfs) 1.08 C =Weir Coefficient 3.33 (per COB Design Standards) H = Head (ft) 1.5 L = Horizontal Length (ft) 0.18 L =Slot Width (inches) 2.1 MANNING'S EQUATION FOR PIPE FLOW Project: Boulder Creek Location: Detention Pond#5 18" Outlet Pipe Capacity By: ADM Date: 4/3/2015 Chk. By: Date: Clear Data Entry 0 Cells INPUT D= 18 inches d= 16.88 inches Mannings Formula d n= 0.013 mannings D 0= 57.7 degrees Q=(1.486/n)ARh213S112 S= 0.0119 slope in/in R=A/P A=cross sectional area P=wetted perimeter V=(1.49/n)R'21IS112 S=slope of channel Q=V X A n=Manning's roughness coefficient Solution to Mannings Equation Manning's n-values Wetted Hydraulic Area,ft2 Perimeter,ft Radius,ft velocity ft/s flow,cfs PVC 0.013 1.72 3.96 0.44 7.16 12.33 PE(<9"dia) 0.015 PE(>12"dia) 0.02 PE(9-12"dia) 0.017 CMP 0.025 ADS N12 0.012 HCMP 0.023 Conc 0.013 MANNING'S EQUATION FOR PIPE FLOW Project: Boulder Creek Location: Detention Pond #5 18" Outlet Pipe Peak Flow By: ADM Date: 4/3/2015 Chk. By: Date: Clear Data Entry 0 Cells INPUT D= 18 inches d= 12.50 inches Mannings Formula d n= 0.013 mannings D 0= 134.3 degrees Q=(1.486/n)ARh213St12 S= 0.0119 slope in/in R=A/P A=cross sectional area P=wetted perimeter V=(1.49/n)Rh213Sv2 S=slope of channel Q=V X A n=Manning's roughness coefficient Solution to Mannings Equation Manning's n-values Wetted Hydraulic Area,ft2 Perimeter,ft Radius,ft velocity ft/s flow,cfs PVC 0.013 1.31 2.95 0.44 7.25 9.49 PE(<9"dia) 0.015 PE(>12"dia) 0.02 PE(9-12"dia) 0.017 CMP 0.025 ADS N12 0.012 HCMP 0.023 Conc 0.013 MANNING'S EQUATION FOR PIPE FLOW Project: Boulder Creek Location: Detention Pond#6 15" Outlet Pipe Capacity By: ADM Date: 4/3/2015 Chk. 13y: Date: Clear Data Entry 0 — - Cells INPUT D= 15 inches d= 14.07 inches Mannings Formula d \/ n 0.013 mannings D 0= 57.7 degrees Q=(1.486/n)ARh21IS11 S- 0.0054 slope in/in R=A/P -- - A=cross sectional area P=wetted perimeter V=(1.49/n)Rh2135112 S=slope of channel Q=V X A n=Manning's roughness coefficient Solution to Mannings Equation Manning's n-values Wetted Hydraulic Area,ft2 Perimeter,ft Radius,ft velocity ft/s flow,cfs PVC 0.013 1.20 3.30 0.36 4.27 5.11 PE(<9"dia) 0.015 PE(>12"dia) 0.02 PE(9-12"dia) 0.017 CMP 0.025 ADS N12 0.012 HCMP 0.023 Conc 0.013 MANNING'S EQUATION FOR PIPE FLOW Project: Boulder Creek Location: Detention Pond #6 15" Outlet Pipe Peak Flow By: ADM Date: 4/3/2015 Chk. Icy: Date: Clear Data Entry Cells i INPUT D= 15 inches d= 8.10 inches Mannings Formula d n 0.013 mannings D 0= 170.8 degrees Q=(1.486/n)ARh21IS112 S= 0.0054 slope in/in R=A/P A=cross sectional area P=wetted perimeter V=(1.49/n)Rh21IS112 S=slope of channel Q=V X A n=Manning's roughness coefficient Solution to Mannings Equation Manning's n-values Wetted Hydraulic Area,ft2 Perimeter,ft Radius,ft velocity fUs flow,cfs PVC 0.013 0.68 2.06 0.33 3.99 2.70 PE(<9"dia) 0.015 PE(>12"dia) 0.02 PE(9-12"dia) 0.017 CMP 0.025 ADS N12 0.012 HCMPJ 0.023 Conc 0.013 MANNING'S EQUATION FOR PIPE FLOW Project: Boulder Creek Location: Detention Pond#8 15" Outlet Pipe Capacity By: ADM Date: 4/3/2015 Chk. By: Date: Clear Data Entry 0 Cells INPUT D= 15 inches d= 14.07 inches Mannings Formula d n= 0.013 mannings D 0= 57.7 degrees Q=(1.486/n)ARh2i3S1i2 S= 0.0059 slope in/in R=A/P A=cross sectional area P=wetted perimeter V=(1.49/n)Rh213SI12 S=slope of channel Q=V X A n=Manning's roughness coefficient Solution to Mannings Equation Manning's n-values Wetted Hydraulic Area,ft2 Perimeter,ft Radius,ft velocity ft/s flow,cfs PVC 0.013 1.20 3.30 0.36 4.46 5.34 PE(<9"dia) 0.015 PE(>12"dia) 0.02 PE(9-12"dia) 0.017 CMP 0.025 ADS N12 0.012 HCMP 0.023 Conc 0.013 MANNING'S EQUATION FOR PIPE FLOW Project: Boulder Creek Location: Detention Pond#8 15" Outlet Pipe Peak Flow By: ADM Date: 4/3/2015 Chk. By: Date: Clear Data Entry 0 Cells INPUT D= 15 inches d= 11.22 inches Mannings Formula d P n= 0.013 mannings D 0= 120.5 degrees Q=(1.486/n)ARh213S112 S= 0.0059 slope in/in R=A/P A=cross sectional area P=wetted perimeter V=(1.49/n)Rh21IS112 S=slope of channel Q=V X A n=Manning's roughness coefficient Solution to Mannings Equation Manning's n-values Wetted Hydraulic Area,ft2 Perimeter,ft Radius,ft velocity ft/s flow,cfs PVC 0.013 0.98 2.61 0.38 4.58 4.51 PE(<9"dia) 0.015 PE(>12"dia) 0.02 PE(9-12"dia) 0.017 CMP 0.025 ADS N12 0.012 HCMP 0.023 Conc 0.013