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Home My WebLink About17 - Design Report - McChesney Work-Live - Stormwater ENGINEERING CONSULTING g,�/�!{�t �y/� p[qq��* PLANNING a fYtiiINEERI G4 INC DESIGN A9 NORT14 11th AVENUE,807.EMAN,MT59715 204N.1VAve BOZENAAN,NT 597 5 0 5&1.AIQ WWA,g i.net Storm Water Management Design Report McChesney Work-Live 623 Nikles Drive Lot 16, McChesney Industrial Park, COS 325 Bozeman, Montana March 2017 Prepared By: Genesis Engineering, Inc. GEI Project#: 1086.009 Prepared For: Longshot Equity, LLC 1871 South 22"'Avenue,Suite 4 Bozeman, MT 59718 204 N. 1111 Ave., Bozeman,MT 59715 Coll:(406)581-3319 wvnv.a-e-i.rtet Page 1 of 7 NGt#JSHRiNG,1tdC '%r'B�u.T-"a c�s>Nss'.S'�'`!ej'sbangcanr Storm Water Management Design Report Table of Contents 1. Project Background.............................................................................................................. 3 1. Introduction............................................................................................................................... 3 2. Soil and Groundwater..........................................................................................................- 3 3. Land Use..................................................................................................................................... 3 11. Existing Conditions.................................................................................................................. 3 1. Drainage Basins and Pre-Development Peak Flows............................................................ 4 Ill. Proposed Drainage Plan and Post-Development Peak Flows........................................ 4 1. Major Drainage Systern........................................................................................................... 5 2. As-Built Storm Main ............................................................................................................... 5 3. Minor Drainage System........................................................................................................... 5 4. Maintenance............................................................................................................................. 6 IV.Conclusion................................................................................................................................ 6 List of Tables Table 1. Estimated Pre-Development Peak Flows..................... .................................................. .......... 4 Table 2. Estimated Capacity of Existing Drainage Conveyance Structures........................................ 4 Table 3. Estimated Post-Development Peak Flows,................... ...................................................... ... 5 Table 4. Proposed Storm Detention Pond........ ........................... ...........................................................5 Table 5. Proposed Drainage Conveyance Structures Capacities............................................................6 Appendix A—Exhibits and Calculations Grading and Drainage Exhibits Pre/Post Development Drainage Basin Flows Conveyance Structure Modeling List of References City of Bozeman Design Standards and Specifications Policy, March 2004, and all addenda. 204 N. 11"Ave.,Bozeman,MT 59715 Cell:(406)581-3319 wwuv. -e-i.net Page 2 of 7 x� i I NGINEERING,INC �ra�niyP Js,rs5_arua.,d'.�reuna 1. Project Background Introduction The McChesney Work-Live project consists of 13, 2-story,work/live units held within four �� g _ buildings, located at 023 Nikles Drive on Lot 16 � � � � � ,� � �� - ;� �. of the McChesney Industrial Park. The existing lot covers approximately 0.98 acres in Section ss 1,T2S, R5E, PMM in Bozernan, Montana. The r property lies north of Interstate 90,east of North 7"'Avenue, and south of West Griffin �� Drive. This design report outlines the storm water ` analysis conducted for the site and describes the storm water drainage and managementM3 facilities required for the Site by state and locale regulations. The storm water plan follows the � design standards set forth by the City of " Bozeman in Design Standards and t� Specifications Policy, March 2004 and three � �" subsequent addenda. Soil and Groundwater The MRCS Soil Survey identifies the major soil �� ? RM, ,. .. type on the site to be Blackdog-Quagle Silt Loam (450C). This soil belongs to hydrologic soil group C as it is comprised primarily of silty Figure I: USGS Topo vicinity map of Offsite Basin A. loam with moderate saturated hydraulic conductivity. A geotechnical investigation is being completed by a geotechnical engineer,and groundwater is expected to be greater than 72 inches deep. The presence of groundwater will not likely affect construction methods. However,based on this information any proposed ponds should likely have dry,vegetated pond bottoms. Land Use The pre-development land use on the site was a vacant lot from the original McChesney Industrial Park. The land is currently zoned B-2 and the proposed use is 13 work/live units. 11. Existing Conditions The Project Site lies north of Interstate 90 and just south of West Griffin Drive. The project's land slopes generally to the east at an approximate average grade of 5.5%. The existing high point of the property is located on the southwestern boundary corner with the low point being on the north eastern boundary corner. The existing topography of the overall site conveys runoff to an unnamed ditch approximately 300 feet east of the site. 204 N. 11`"Ave.,Bozeman,MT 59715 Cell: 406 581-3319 wv. _�( ) q-e-i.net Page 3 of 7 �,_ PJ+�tN�I�RfNt�,11VC Drainage Basins and Pre-development Peak Flaws Genesis identified the major contributing drainage basin from lands offsite and other onsite drainage basins as shown on exhibit GD1 found in Appendix A. The OS-A drainage basin stretches from the outfall on the subject property's west line for approximately 400 feet to the west, ending at the centerline of North 7th Avenue. Estimates of runoff and their respective calculations for the more local existing drainage basins were completed using the Modified Rational Method. Our offsite basin model uses a pre-development runoff coefficient of C=0.20 which does not necessarily represent the typical ground cover we see today. The local basin also use a pre-development runoff coefficient of C=0.20. Genesis looked at storm return intervals such as the 10-year,25 year and 100-yr during the analysis of the existing storm water conveyance structures in or near the site. A summary of estimated pre-development peak runoff rates as well as existing drainage conveyance structure capacities can be found in Tables 1 and 2. Detailed calculations are availahle in Annendix A. Table 1. Estimated Pre-Development Peak Flaws(see GD-1) Sub Area Description Area Tc Q10 Q25 Q100 (acres) Amin) ___f cfsj_ -Acfs) (cfsj OS-A Offsite Basin 1.7 16 0.5 0.6 0.8 OS-A&A All Basins w/same outfall 2.6 1.6 1.0 1.3 Al Onsite Basin 0,24 9 0.1 0.1 0.2 A2 Onsite Basin 0.51. 11. 0.2 0.2 0A B1 Onsite Basin 0.17 9 0.1 0.1 0.1 A Onsite Pond Basin 0.91 15 0.3 0.3 0.5 Table 2. Existing Drainage Conveyance Structure Capacities Description Depth Slope Contrib. Q25post Struct.Cap. Passes {ft) W Areas {cfs) {cfs) 25-YR 15"A-2000 1.25 1 A&OS-A 4.8 6.7 Y III. Proposed Drainage Plan and Estimated Post-Development Peak Flows The proposed drainage plan shall build off of the existing or natural drainage system in place. Genesis' drainage plan really consists of two separate drainage systems. First,the major drainage system or backbone is designed to have a much higher conveyance capacity and .shall convey the excess runoff from the 1.00-year storm without inundating any building structures. Secondly, the minor drainage system fits within the major drainage system and feeds into it. The minor drainage system(s)are designed to accommodate moderate and relatively frequent storm events without inconveniencing the public. The minor system is comprised of the streets,inlets, and swales designed to convey runoff from the 25-year event,and the detention pond designed to attenuate the 10-year storm event. Table 3 presents a summary of the expected post-development peak flow rates passing through the proposed project. 204 N. 11"Ave.,Bozeman,N)T 59715 Cell:(406)581-3319 Page 4 of 7 a SS � NGINEERING INC Table 3. Estimated Post-Development Peak Flows(see GD-1) Sub Area Description Area C Tc Q10 Q25 Q100 ____LacresL Iminj_ OS-A Offsite Basin 1.7 0.7.5 10 2.7 3.1, 4.3 OS-A&A All Basins w/same outfall 2.6 0.75 10 4.8 6.5 Al Onsite Basin 0.24 0.67 7 0.4 0.5 0.7 A2 Onsite Basin 0.51 0.78 9 0.9 1.0 1.4 B1 Onsite Basin 0.17 0.70 6 0.4 0.4 0.6 A Site Pond Basin 0.91 0.74 12 1.3 1.5 2.0 Major Drainage System The major drainage system in the area is comprised of the unnamed ditch to the east of the subject parcel. The existing 15" HDPE pipe has adequate street conveyance capacity to convey the 100-yr event through the development and into the unnamed ditch to the east without inundating the first floor of the proposed structures. Based on the proposed first floor elevations and capacity of the unnamed ditch to the east as modeled in the Great Northern Storm Water Design Report,we do not anticipate the structures being inundated by storm events up to and including the 100-yr event. Minor Drainage System The proposed minor drainage system for the McChesney Work/Live Units includes a single, interior, parking lot with sheet flow directed into a curb inlet generally located in the center of the project. A valley gutter is proposed to direct runoff from the southeastern parking area into a second curb inlet.Those curb inlets will convey storm water runoff to the detention pond shown on GD-2. A Swale, beginning at the northwestern property corner,conveys offsite runoff east,into one of the proposed stormwater inlets,eventually flowing into the existing 15" HDPE pipe and into the east unnamed ditch. The detention pond is sized to detain the onsite, 10-year storm flows as required. Discharge from the pond is to be conveyed through the outlet structure, into a storm pipe flowing north into one of the proposed storm inlets,and eventually into the existing 15" HDPE pipe.A second swale, located in the southern area of the project will convey runoff away from the buildings and proposed sidewalk through a 12"sidewalk chase to the parking lot where it will flow as previously discussed. Once the 25-year event leaves the site, it will be conveyed through the existing 15" HDPE pipe and eventually to flow into the unnamed ditch to the east. The catch curb and gutter of each of the parking lots will convey an estimated 5 cfs before inundating the adjacent sidewalk which is many times greater than the 100-year flow rate contributed by impervious area on site-Basin A2. The proposed north Swale conveying runoff to a stormwater inlet has a capacity of 12 cfs which is greater than the runoff contributed by Offsite Basin A(assumed fully developed)that feeds the Swale during the 100-Yr Storm.The pipe leaving the detention pond is a 12"A-2000 pipe that conveys the runoff from of Basin A, has a capacity of 5.2 cfs,which is many times greater than the 100-year storm.The proposed inlet and pipe on the western boundary has a capacity of 6 cfs which is exceeds the contributing Basin OS-A 100-year post development event.The proposed south Swale conveying runoff to the sidewalk chase has a capacity of 1-2 cfs which is greater than the runoff contributed by part the site's local Basin Al during the 100-Yr Storm. The sidewalk chase that conveys the runoff from part of Basin Al, has a capacity of 3.5 cfs,which is many times greater than the 100-year storm. The proposed pipes from the curb inlets have a capacity of 6 9 cfs which is many times greater than the 100-year flow for Basin A. The proposed storm pond was sized to handle all the intended contributing area, using a future developed ground cover condition of 0.74. The pipe from the pond to the existing system is a 12"A-2000 with a capacity of 5 cfs,which is greater than the 25-year post development flow. Table 4. Detention Pond Volume(See GD-2) Pond Type Depth Contributing Q10 PST Req.Vol. Avail.Vol. Detains ea�___---.- jcfs� jcftj�-.--__ cfa __-------.._Design storm 1. Detention 1.5' Al,A2,B1 1.3 755 757 Y 204 N. IV`Ave., Bozeman.MT 59715 Cell:(406)581-3319 wtin^�.q-e-i.net Page 5 of 7 NCINEi2iNG,INC Table 5. Proposed Drainage Conveyance Structure Capacities(See GD-2) Description Contributing Depth Slope Q10PST Q25PST Q10OPST Qcap Passes Subareas 1ftL__ LL_ (cfs) Ids) (cfsl jcfs Demon Storm _ Site-Catch Curb and Gutter A2 0.3 0.5 0.9 1.0 1.4 4.7 Y Site-North Swale OS-A 1.0 1.0 2.7 3.1 4.3 12 Y Site-west Pips: OS-A 1.0 1 7 2.7 3A 4.3 6.0 Y Site-South Swale Al 05 1.0 0.4 0.5 0.7 2.0 Y Site-Sidewalk Chase At 0.5 2.0 0A 0.5 0.7 3.S Y Site-Curb Inlet Pipe Al,A2,61 1.0 1.7-4.1 1.3 1.5 2.0 6-9 Y Site-Pond Pipe Al,A2,131 1.0 L 2 4 1.3 1-s 2.0 5 Y Outlet Structure weir Al.,A2, 31 1.5 Q10pre=0.29 0.29 Y Outlet Structure Top Inlet Al,A2,Bi 1.s Y Maintenance Regular maintenance of storm water facilities is necessary for proper functioning of the drainage system. In general, regular mowing of any grass swales and storage ponds and unclogging of inlets and outlet works will be required to prevent standing water,clogging, and the growth of weeds and wetland plants. More substantial maintenance,such as sediment removal with heavy equipment, may be required in coming decades to restore detention pond volume. All maintenance and repair should be prioritized and scheduled in advance. Inlets&pipes should be visually inspected yearly. Typical maintenance items include removing obstructions,cleaning and flushing pipes, mowing grass and weeds,tree maintenance to prevent limbs from falling and blocking swales,and establishing groundcover on bare ground. IV. Conclusion Storm water analysis and calculations indicate that the proposed storm water management plan for the proposed site plan is adequate to safely convey the 10-year, 25-year, and 100-year storm events while satisfying state and local regulations for peak attenuation and storm water storage. No hazardous backwater affects from downstream structures have been observed to affect the proposed site plan. The project as planned and described within this report will not have any significant adverse effects on any neighboring properties. Furthermore,the proposed first floor elevation for the proposed structures are above the estimated 100-yr Base flood Elevations as estimated by Genesis Engineering. i-i:\1086\009\DOCS\DESIGN\STORM\StormwaterDR.doc 204 N. 111"Ave.,Bozeman,MT 59715 Cell:(406)581-3319 yww.w.g-e-i.n2t Page 6 of 7 SIS NGINEERING,INC Appendix A Exhibits & Calculations 204 N. 11"Ave., Bozeman,MT 59715 Cell: 406 .( },581..3319 MwAVcue-i.nel '1 Page 7 of 7 B w m >j 4 K w u:n z I t t LN ._..... \? Q r , _n ........... a „ •D 4 i _ a u> rnwW LuO w �...... .. O yxY W 9 J'Lyll rD ,',;. ,ay 2.. : iwW w , co 4 I , - I I` r gg 1 i 3 t rr 1 I� — ✓ l 3 ILL,:� (!j'}} r cx mow r � j IN ' I � lit Elk— i 3^ , i t YF McChesney Work/Live 3/8/2017 BASIN OS-A BASIN B1 Weighted C Weighted C Residential(C=.45) Area(sf) 7200 Commercial(C=.70) X Area(Acres) 0.17 Industrial(C= .80) Area Impervious(0.9) 5184 Area Grass(0.2) 2016 Weighted C= 035 Weighted C= 0.70 BASIN Al BASIN A2 SINGLE POND - BASIN Weighted C Weighted C Weighted C Area(sf) 10274 Area(sf) 22040 Area(sf) 39514 Area(Acres) 0.24 Area(Acres) 0.51 Area(Acres) 0.91 Area Impervious(0.9) 6925 Area Impervious(0.9) 18135 Area Impervious(0.9) 30244 Area Grass(0.2) 3349 Area Grass(0.2) 3905 Area Grass(0.2) 9270 Weighted C= 0.67 Weighted C= 0.78 Weighted C= 0.74 GEI#: 1.086.009 DATE: 3/8/20.17 ENGINEER: Joel Horn DES"-Pond-A-10yr NESIS MODIFIED RATIONAL METHOD NGINEERING, INC Qp=CIA 204 N,l l l,*,A^£. +�" .'�..Y?SE,€arv:,tAY�'�371�i PRE-DEVELOPMENT RAINFALL FREQ 10 YR(DURATION=1) 1=A'(Tc/60) (CITY OF BOZEMAN) BASIN AREA PRE= 0.91 AC STORM EVENT STORM i COEFF INTENSITY YR A B IN HR PRE.-DEV Tc= 1.5.0 MIN 2 0.36_ 0.6 0.83 5 0.52 0.64 1.26 PRE-DEV C 0.20 10 0.64 0.66 1.60 25 0.78 0.64 i.89 STORM A= 0.64 SO 0.92 0.66 2.30 B= 0.66 100 1.01 0.67 2.56 STORM INTENSITY= 1.60 IN/HR PRE-DEV Qp= 0.29 CFS POST-DEVELOPMENT POND VOLUME: a dNST.RELEASE BASIN AREA PRE= 0.91 AC 585.85 POST-DEVTc= 12.0 MIN TMANtGLEfi:LCASF DETENTION (C.F); POST-DEV C= 0.74 c}23 3 STORMINTF.NSITY= 1.85 IN/HR � a',YMAGE\OLUME ' �CFt POST-DEV Qp= 1.25 CFS 754.6u. OUTLET STRUCTURE DESIGN RETENTION, (CO POND: DET-Pond-A-10yr 1?87:R REQUIRED VOL= 754.62 CF (AVG.a;wCONS). IR(ANGLE.RCLEASE! DIAMETER= 6.00 IN LENGTH OF PIPE= 10.00 FT QPRE= 0.29 CFS HEAD WATER 0.50 Ft AREA- 0.08 SF N= 0.012 ORIFICE= 4 1/2 IN Ke= 0,50 ORIFICE FLOW= 0.28 CFS SLOPE OF PIPE= 0.005 FT'/FT FLOW OUT 0.24 CFS "FLOW GOOD AVE SURF AREA- 1171.70 SF H:\1086\009\DOCS\DESIGN\S"(ORM\SINGLE POND.xIs 1 OF 2 PRINTED: 3/13/2017 DET-Pond-A-10yr POND VOLUME CALC'S OUTLET STRUCUTRE CALC'S 1`riangle Release Constant Release SLOPE OF ENERGY ORIFICE DURATION INTENSITY Qp POND VOLUME POND VOLUME PIPE FLOW OUT (MIN) (IN/HR) (CFS) (CF) (CF) (FT-/FT) (CFS) (CFS) 11.40 1..92 1.29 677.98 521.04 0.000 0.000 0.279 12,40 1,81. 1.22 694.84 531.87 0.001 0.1.07 13.40 1.72 1.16 710.37 541.30 0.002 0.151 14,40 1.64 1.11 724.73 549.49 0,003 0.185 1S,40 L57 1.06 738.06 556.59 0.004 0.214 1.6.10 1.51 1.01 750.46 562.71 0.005 0.239 17.40 1.45 0.98 762.03 567.95 0.006 0.262 18,40 1.40 0.94 772.84 572.38 0.007 0.283 19.40 1.35 0.91 782.96 576,08 0.008 0.303 20,40 1.30 0.88 792.46 579.11. 0.009 0.321 21.40 1.26 0.85 801.37 58LS2 0.010 0.338 22.40 1.23 0.83 809.74 583,36 0.01.1 0.355 23.40 1,19 0.80 817.62 584,68 0.012 0.371 24.40 1.16 0.78 82.5.04 585.49 0,013 0.386 25.40 1.13 0.76 832D3 585.85 0.014 0.400 26.40 1,1.0 0.74 838.61 585,78 0.015 0.414 27,40 1.07 0.72 844.82 58530 0.016, 0.428 28.40 1.05 0.71 850.67 584.44 0.017 0.441 29.40 1,02 0.69 856.18 583,23 0.01.8 0.454 30.40 1.00 0.69 861.38 581.67 0.019 0.466 31.40 0,98 0.66 866.28 S7939 0.020 0.479 32.40 0.96 0.65 870.90 577.61. 0.021 0.490 33.40 0.94 0.63 875.24 575.14 0.022 0.502 34.40 0.92 0.62 879.34 572.40 0.023 0.513 35.40 0.91. 0.61, 883.1.8 569.39 0.024 0.524 36A0 0.89 0.60 886.80 566.13 0.025 0,535 37.40 0.87 0.59 890.19 562,63 0.026 0.546 38.40 0.86 0.58 893.28 558.91. 0.027 0.556 39.40 0,84 0.57 896.35 554.96 0.028 0.566 40.40 0.83 0.56 899,14 550.81 0.029 0.S76 41.40 0.82 0,55 901.74 546.45 0.030 0.586 42.40 0.80 0.54 904.16 541.90 0.03:1 0.596 43.40 0.79 O.S3 906.40 537.17 0.032 0.605 44.40 0.78 0.53 908.48 532.25 0.033 0.615 45.40 0,77 0.52 910.41 527.17 0.034 0,624 46.40 0.76 0,51, 912.1,7 521.91 0.035 0.633 47,40 0.75 0.50 913.79 516.50 0.036 0.642 48.40 0.74 0.50 915.27 51.0.93 0.037 0.65:1. 49.40 0.73 0.49 916.61 505.21 0,038 0.660 50.40 0.72 0.48 917,81 499.34 0.039 0.668 51.40 0.71 0,48 918.89 493.34 0,040 0.677 H:\1086\009\ROCS\DESIGN\STORM\SINGLE POND.xIs 2 OF 2 PRINTED: 3/13/2017 Pond olu e Detention Pond -A Layer Elevation Area Volume (ft) (sgft) (cft) 4706 252 4706.5 397 162.25 4707 585 245.5 4707.5 811 349 Total 756.75 cft NG1NEERI IG, INC iXJSetBrptnninfjofa.A1t 9aaanfafComXitmeat McChesney Work-Live Engineer: J. May 03/13/17 36" Round Outlet Structure - Pond A 10 year pre 0.29 cfs 25 year post 1.47 cfs Using COB Weir Equation 10 yr flow through slot = CLHA(3/2) Q= 3.33-L-1.5(3/2) 0.29 cfs L=0.047' :t , 4 m wide During storms greater than the 10 year, some additional flow will overtop the weir and flow through the outlet pipe. Remainder of flow up will enter the inlet on top of the structure. GEItt: 1,086.009 DATE: :3/9/2.017 ENGINEER: Joel Horn BASIN A- 10yr NESIS MODIFIED RATIONAL METHOD ' NGINEERING, INC Qp=CIA F,J.t N, £YRAJ t:. JIY�.£d. �+t y"e'16 Cr:.gf�Y �0 PRE-DEVELOPMENT RAINFALL-FREQ 10 YR(DURATION=1) 1=A*(Tc/60) (CITY OF BOZEMAN) BASIN AREA PRE:= 0.91 AC STORM EVENT STORM i COEFF INTENSITY (YFtI _ A B (IN HR PRE-DEVTc= 15.0 MIN _2 0.36 0.6 0.83 S 0.52 0.64 1.26 PRE-DEV C= 0.20 10 0.64 0,66 1,60 25 0.78 0,64 1.89 STORM A= 0.64 SO 0.92 0.66 2.30 B= 0.66 100 1.01 0.67 2.56 STORM INTENSITY= 1.60 IN/HR PRE-DEV Qp= 0.29 CFS POST-DEVELOPMENT BASIN AREA PRE= 0,91 AC POST-DEVTc= 12.0 MIN POST-DEV C= 0.74 STORM INTENSITY= 1.85 IN/HR POST-DEV Qp= 1.25 CFS H:\1086\009\DOCS\DESIGN\STORM\Basin A-10yr As 1 OF 1 PRINTED 3/13/2017 GE11t: 1086.009 DATE: 3/9/2017 ENGINEER: Joel Horn BASIN A- 25yrNESIS � , MODIFIED RATIONAL METHOD NGINEERI G, INC Qp=CiA 2',D4N.91ri A- 4' !3�T:S.tnN..M7 �:`•Pi •'.Z?E+?if31^t7�:) PRE-DEVELOPMENT RAINFALL FREQ 25 YR(DURATION 1) i=A'(Tr./60) (CITY OF BOZEMAN) BASIN AREA PRE 0.91 AC STORM EVENT STORM i COEFF INTENSITY ____JYRL A B IN HR PRE-DEV'1'c= 15,0 MIN 2 �0.36 0.6 0.83 5 0.52 0.64 1.26 PRE-DEV C= 0.20 10 0.64 0.66 1.60 25 0.78 0.64 1.89 STORM A= 0.78 so 0.92 0.66 2.30 B= 0.64 100 1.01 0.67 2.56 STORM INTENSITY= 1.89 IN/HR PRE-DEV Qp= 0.34 CFS POST-DEVELOPMENT BASIN AREA PRE= 0,91 AC PO.S'i'-DF.VTc= 12.0 MIN POST-DEV C= 0,74 STORM INTENSITY= 2A8 IN/HR POST-DEV Qp= 1.47 CF5 H:\1086\009\DOCS\DESIGN\STORM\Basin A-25yr.xls 1 OF 1 PRINTED 3/13/2017 GE14: 1.086.009 DATE: 3/9/2017 ENGINEER: Joel Horn BASIN A - 100yr NESIS MODIFIED RATIONAL METHOD NG N RING, INC Qp'=CiA PRE-DEVELOPMENT RAINFALL FREQ= 100 YR(DURATION=1) i=A'(Tc%60) " (CITY OF BOZEMAN) BASIN AREA PRE- 0.91 AC STORM EVENT STORM i COEFF INTENSITY YR A B (IN JAR PRE-DEV Ic= 15.0 MIN W 2 �0.36 0.6 0.83 5 Q52 0.64 1.26 PRE-DEV C- 0.20 10 0.64 0.66 1.60 25 0.78 0.64 1.89 STORM A= 1.01 50 0.92 0.66 2.30 B= 0.67 100 1.01 0.67 2.56 STORM INTENSITY= 2.56 IN/HR PRE-DEV Qp= 0.47 CF5 POST-DEVELOPMENT BASIN AREA PRE.= 0.91 AC POST-DEV Tc= 12.0 MIN POST-DEV C= 0.74 STORM INTENSIFY= 2.97 IN/HR POST-DEV Qp= 2.00 CFS H:\1086\009\DOGS\DESIGN\STORM\Basin A-100yr.xls 1 OF 1 PRINTED: 3/13/2017 GEI#: 1096.009 DATE: 3/9/2017 ENGINEER: Joel Horn BASIN Al - soyr NESIS MODIFIED RATIONAL METHOD NGINEERINGy INC Qp-CIA PRE-DEVELOPMENT RAINFALL.FREQ'= 10 YR(DURATION 1) i=A`(I c/60) " (CITY OF BOZEMAN) BASIN AREA PRE-= 0,24 AC STORM EVENT STORM i COEFF INTENSITY YR A B IN IAR PRE-DEV Tc= 9.0 MIN 2 0.36 0,6 1.12 S 0.52 0.64 1,75 PRE-DEV C= 0.20 10 0,64 0.66 2,24 25 0.78 0.64 2.6.3 STORM A= 0.64 so 0.92 0.66 3.22 B 0.66 100 1.01 0.67 3.60 STORM INTENSITY= 2.24 IN/HR PRE-DEV Qp= 0.11 CFS POST-DEVELOPMENT BASIN AREA PRE= 024 AC POai'-DEVTc= 7.0 MIN POST-DEV C= 0.67 STORM INTENSITY= 2,64 IN/HR POST-DEV Qp= 0.42 CFS I-i\1086\009\DOGS\DESIGN\STORM\Basin Al-10yr.xls 1 OF 1 PRINTED' 3/13/2017 GEId#: 1086.009 DATE: 3/9/2017 ENGINEER: Joel Horn BASIN Al - 25yr MODIFIED RATIONAL METHOD NGINEERING, INC Qp=CIA 2,4,11-11—All' e" :,,p1€,,, IT 3J715 PRE-DEVELOPMENT RAINFALL.FREQ= 25 YR(DURATION=1) 1=A`(Tc/60)'` (CITY OF BOZEMAN) BASIN AREA PRE= 0.24 AC STORM EVENT STORM i COEFF INTENSITY YR _ A _ IN%FiR PRE-DEV'Fc= 9.0 MIN _ 2� �0.36 0.6 1-1.2 5 Q.S2 0.64 1.75 PRE-DEV C= 0.20 10 0.64 0.66 2.24 25 0.78 0.64 2.63 5I'ORM A= 0.78 SO 0.92 0.66 3.22 B= 0.64 1.00 1..01 0.67 3.60 STORM INTENSITY= 2.63 IN/HR PRE-DEV Qp= 0.13 CFS POST-DEVELOPMENT BASIN AREA PRE= 0.24 AC: POST-DEV TC= 7.0 MIN POST-DEV C= 0.67 STORM IN'T E.NSITY= 3.08 IN/HR POST-DEV Qp= 0.50 CFS H'\1086\009\DOGS\DESIGN\STORM\Basin Al-25yr.xls 1 OF 1 PRINTED: 3/13/2017 GEI#: 1086.009 DATE: 3/9/2017 ENGINEER: Joel Horn BASIN Al - 100yr w MODIFIED RATIONAL METHOD NGINEE III G, IN Qp=CiA PRE-DEVELOPMENT RAINFALL FREQ= 100 YR(DURATION 1) 1=A ('Fc/60) ° (CITY OF B07EIViAN) BASIN AREA PRE= 0.24 AC STORM EVENT STORM i COEFF INTENSITY LR) _A B IN/HR PRE-DEV Tc= 9.0 MIN 2 0.36 _0.6 1.12 5 0.52 0.64 1.75 PRE-DLV C= 0.20 10 0.64 0.66 2.24 25 0.78 0.64 2.63 STORM A= 1.01 50 0.92 0.66 3.22 B= 0.67 1.00 1_01 0.67 3.60 STORM INTENSITY= 3.60 IN/HR PRE-DEV Qp= 0.17 CFS POST-DEVELOPMENT BASIN AREA PRE= 0.24 AC POS?'-DEVTc= TO MIN POST-DEV C= 0.67 STORM INTENSITY= 4.26 IN/HR POST-DEV Qp= 0.69 CFS H:\1086\009\DOCS\DESIGN\STORM\Basin A1-100yi.xis 1 OF 1 PRINTED: 3/13/2017 GE11t: 1.086.009 DATE: 3/9/20.17 ENGINEER: Ioel Horn BASIN A2 - 10yr MODIFIED RATIONAL METHOD NGINEERING, INC Qp=CiA 2oa t:nr 9a�i;. b;Ktnt.. hti,^9'l 15 af;+a°i3i;x3tih PRE-DEVELOPMENT RAINFALL FREQ 10 YR(DURATION=1) 1=A`(Tc/60) " (CITY OF BOZEMAN) BASIN AREA PRE= 0.51 AC STORM EVENT STORM i COEFF INTENSITY YR A B N IiR PRE-DEV I= 11-0 MIN 2 _0.36 0.6 1,00 5 0,52 0.64 1.54 PRE-DEV C= 0.20 10 0.64 0.66 1.96 25 0.78 0.64 2,31, STORM A= 0.64 50 0.92 0.66 2.82 B= 0.66 100 1.01 0.67 3.15 STORM INTENSITY= 1.96 IN/FIR PRE-DEV Qp= 0.20 US POST-DEVELOPMENT BASIN AREA PRE= 0.51 AC POST-DEVTc= 9.0 MIN POST-DEV C= 0.78 STORM INTENSITY= 2,24 IN/HR POST-DEV Qp= 0.89 CFS H:\1086\009\DOGS\DESIGN\STORM\Basin A2-10yr.xls 1 OF 1 PRINTED: 3/13/201 GEI#: 1,086.009 DATE: :3/9,2017 ENGINEER: Joel Horn BASIN A2-25yr � MODIFIED RATIONAL METHOD NGINEERING, INC Qp=CiA 2. •7 3!'r'>'A• H.yT�•Fn+;.!.k'i:i;37., t -, - 9�C.:5�8 PRE-DEVELOPMENT RAINFALL FREQ 25 YR(DURATION 1) 1=A`(Fc/60) ` (CITY OF BOZEMAN) BASIN AREA PRE= 0.5.1 AC STORM EVEN] STORM i COUT INTENSITY YR _ A B N/IiR PRE-DEV Tc= 11.0 MIN 2 0,36 0.6 1..00 5 0.52 0.64 1.54 PRE-DEV C= 0.20 10 0,64 0.66 1,96 25 0.78 0.64 2.31 STORM A= 0,78 so 0.92 0.66 2,82 B 0.64 100 1..01 0.67 3,15 STORM INTENSITY= 2.31, IN/HR PRE-DEV Qp= 0.24 CFS POST-DEVELOPMENT BASIN AREA PRE= 0,51 AC POST-DF..V Tc= 9.0 MIN POST-DEV C= 0.78 SIORMINI'FNSI'IY= 2,63 IN/HR POST-DEV Qp= 1.04 US H:\1086\009\DOSS\DESIGN\STORM\Basin A2-25yr.xis 1 OF 1 PRINTED 3/13/2017 GEM: 1.086.009 DATE: 3/9/2017 ENGINEER: Joel Horn BASIN A2 - 100yr NESI S .. MODIFIED RATIONAL METHOD ISIGINEERINGg INC Qp=CiA .�,Gs ➢ e?x,;rs. .tckz�+xau.ker`:3"�Fk <. .i(;5'S9:3 it:1 PRE-DEVELOPMENT RAINFALL FREQ= 100 YR(DURATION=1) i=A (Tc/60) " (CITY OF BOZE.IVIAN) BASIN AREA PRE 051 AC STORM EVENT STORM i COEFF INTENSITY YR A B (IN HR PRE-DEV'Tc= 11..0 MIN 2 - 0.36 0.6 1.00 5 0.52 0.64 1,54 PRE-DEV C= 0,20 10 0.64 0.66 1,96 2.5 0.78 0.64 2.31. STORM A= 1.01 50 0.92 0.66 2.82 B= 0.67 100 1.01 0.67 3.15 STORM INTENSITY= 3.1.5 IN/HR PRE-DEV Qp= 0,32 CFS POST-DEVELOPMENT BASIN AREA PRE= 0.51. AC POS-1-DEVIc= 9.0 MIN POST-DEV C= 0,78 STORM INTENSITY= 160 IN/HR POST-DEV Qp= 1.43 CF5 H:\1086\009\DOCS\DESIGN\STORM\Basin A2-100yr.xls 1 OF 1 PRINTED 3/13/2017 GEIN: 1,086,009 DATE: 3/9/2017 ENGINEER: Ioel Horn A BASIN B1-10yr .� MODIFIED RATIONAL METHOD NGINEERING, INC Qp=CIA PRE-DEVELOPMENT RAINFALL FREQ 10 YR(DURATION 1) i=A*(Tc/60) t' (CITY OF BOZEMAN) BASIN AREA PRE a- 0.17 AC STORM EVENT STORM i COEFF INTENSITY (YR) A B IN IIR PRE-DEV Tc= 9.0 MIN 2 0,36 0.6 1.12 5 0,52 0.64 1.75 PRE-DEtV C= 0,20 10 0.64 0.66 2,24 25 0.78 0,64 2.63 STORM A= 0.64 50 0,92 0.66 3.22 B= 0,66 100 1.,01 0.67 3.60 STORM INTENSITY 2,24 IN/IIR PRE-DEV Qp= 0.08 CFS POST-DEVELOPMENT BASIN AREA PRE= 0.17 AC POST-DEV Tc= 6.D MIN POST-DEV C= 03 STORM INTENSITY= 2.93 IN/HR POST-DEV Qp= 0.35 CF5 H:\1086\009\DOCS\DESIGN\STORM\Basin B1-10yr.xls 1 OF 1 PRINTED: 3/13/2017 GEI#: 1086.009 DATE: 3/9/2017 ENGINEER: Joel Horn ' BASIN B1-25yr NESIS MODIFIED RATIONAL METHOD a NGINEERINGy NC QP=CiA 2'04N,Jr11,A,e:. �, (9a:zci✓.u.MT`.i9�a"i. ., ar5 53;�?,ra PRE-DEVELOPMENT RAINFALL FREQ 25 YR(DURATION=1) i=A ('I`c/60) " (CITY OF BOZE.MAN) BASIN AREA PRE= 0.17 AC STORM EVENT STORM i COEFF INTENSITY YR _A_ _B IN HR PRE-DEV Tc= 9.0 MIN 2 0.36� 0.6 1.12 5 0.52 0.64 1.75 PRE-DEV C= 0.20 10 0.64 0.66 2.24 25 0.78 0.64 2.63 STORM A= 0.78 50 092 0.66 3.22 B= 0.64 100 1..01 0.67 3.60 STORM INTENSITY= 2.63 IN/HR PRE-DEV Qp= 0.09 CFS POST-DEVELOPMENT BASIN AREA PRE= 0.17 AC POST-DE,.V-1c= 6.0 MIN POSI-DEV C= 03 STORM INTENSITY= 3.40 IN/HR POST-DEV Qp= 0.41 CFS M:\1086\009\DOCS\DESIGN\STORM\Basin B1-25yr.xls 1 OF 1 PRINTED- 3/13/2017 GEI#: 1086.009 DATE: 3/9/20.17 ENGINEER: Joelliorn BASIN 131-100yr NESIS MODIFIED RATIONAL METHOD NGINEERING, INC Qp=CiA PRE-DEVELOPMENT RAINFALL FREQ 1.00 YR(DURATION=.1) i=A (Tc.160) " (CITY OF BOZEMAN) BASIN AREA PRE 0.17 AC STORM EVENT STORM i COEFF INTENSITY YR A B (IN HR PRE-DEVTc= 9.0 MIN 2 036 O.Ei 1-12 5 0.52 0.64 1.75 PRE-DEV C= 0.20 10 0.64 0.66 2.24 25 038 0.64 2.63 STORM A= 1.01 50 0.92 0.66 3.22 B= 0.67 1.00 1.01 0.67 3.60 STORM IN TENSITY 3.60 IN/IlR PRE-DEV Qp= 0.12 CFS POST-DEVELOPMENT BASIN AREA PRE= 0.17 AC POS'i'-DE.VTc= 6.0 MIN POST-DEV C= 0.7 STORM INT ENS]rY= 4.72 IN/HR POST-DEV Qp= 0.56 CFS H:\1086\009\DOCS\DESIGMSTORM\Basin B1-100yr.xls 1 OF 1 PRINTED: 3/13/2017 GEM 1,086.009 DATE: 3/9/2017 ENGINEER: Joel Horn BASIN S-A- 10yr NESIS MODIFIED RATIONAL METHOD NGINEERING, INC Qp=CiA3' :20. 2 1 r.�Av s. :.'Y.IE�,W4.Mr YJ I PRE-DEVELOPMENT RAINFALL FREQ 1.0 YR(DURATION-1) i=A*(Tc/60) ° (CITY OF BOZE.MAN) BASIN AREA PRE= 1.7 AC STORM EVENT STORM i COEFF INTENSITY YR _A B IN FiR PRE-DEV Tc= 1.6.0 MIN 2 0.36 O.6 0,80 5 0.52 0.64 1.2.1. PRE-DEV C= 0,20 10 0.64 0.66 1,53 25 0.78 0.64 1.82. STORM A= 0.64 50 0.92 0.66 2.20 B 0.66 100 1..01 0.67 2..45 STORM INTENSITY= 1.53 IN/I-IR PRE-DEV Qp= 0.52 CFS POST-DEVELOPMENT BASIN AREA PRE= 1.7 AC POST-DEVTc= 10.0 MIN POST-DEV C= 0.75 STORM INTENSITY= 2,09 IN/HR POST-DEV Qp= 2.66 CFS H\1086\009\DOGS\DESIGN\STORM\Basin OS-A-10yr.xls 1 OF 1 PRINTED: 3/13/2017 GEIN: 1086.D09 DATE: 3/9/2017 ENGINEER: Joel Hom BASIN OS-A& Site - 2SYr � MODIFIED RATIONAL METHOD ISIGIN ERING, INC Qp=CiA PRE-DEVELOPMENT RAINFALL FREQ 25 YR(DURATION 1) i=A (Tc/60) " (CITY OF BOZEMAN) BASIN AREA PRE= 1.7 AC STORM EVENT STORM i COEFF INTENSITY (R A B_ IN IiR PRE-DEV Tc 16.0 MIN 2 _ 0.36 0.6 0.80 5 0.52 0.64 1,21 PRE-DEV C= 0.20 10 0.64 0.66 1.53 25 0.78 0.64 1.82 STORM A= 0.78 So 0.92 0.66 2.20 B= 0,64 100 1.01 0.67 2.45 STORM IN"iE_NSITY= 1.82 IN/liR PRE-DEV Qp= 0,62 CFS POST-DEVELOPMENT BASIN AREA PRE= 1.7 AC POST-DEVTc= 10.0 MIN POST-DEV C= 0,75 STORM INTENSITY= 2.46 IN/HR POST-DEV Qp= 3.13 CFS H:\1086\009\DOCS\DESIGN\STORM\Basin OS-A-25yr.xls 1 OF 1 PRINTED: 3/13/2017 GEI#: 1.086.009 DATE: 3/9/2017 ENGINEER: JoelIiorn BASIN OS-A- 10OYr � rNESIS MODIFIED RATIONAL METHOD NGINEERING, INC Qp=CiA PRE-DEVELOPMENT RAINFALL FREQ= 1.00 YR(DURATION-1) 1 A`(Tc.%60) " (CITY OF BOZEMAN) BASIN AREA PRE 1.7 AC STORM EVENT STORM i COEFF INTENSITY Yf A _ B IN HR PRE-DEV Tc= l.Ei.O MIN 2 0.36 0.6 0.80 5 0,52 0.64 1.21 PRE_DEV C= 0,20 10 0.64 0,66 1,:3 25 0.78 0.64 1..82 STORM A= 1.01 50 0.92 0.66 2.20 B= 0.67 100 1,01 0,67 2.45 STORM INTENSITY= 2.45 IN/HR PRE-DEV Qp= 0.83 CFS POST-DEVELOPMENT BASIN AREA PRE= 1.7 AC POST-DE.VTc= 10.0 MIN POST-DEV C= 0,75 STORM INTENSITY= :3.35 IN/HR POST-DEV Qp= 4.28 CFS hi'.\1086\009\DOCS\DESIGN\STORM\Basin OS-A-100yr.xls 1 OF 1 PRINTED. 3/13/2017 GEI#: 1.086.009 DATE: 3/9/20.17 ENGINEER: Joel Horn BASIN OS-A & Site - 25Yr NESIS MODIFIED RATIONAL METHOD NGINEERING, INC Qp=CiA PRE-DEVELOPMENT RAINFALL FREQ= 25 YR(DURATION 1) 1=A (Tc/60) (PITY OF BOZEMAN) BASIN AREA PRE 2.6 AC STORM EVENT STORM i COEFF INTENSITY YR A B _ (IPJ HR PRE-DEVTc= 1.6.0 MIN 2 0.36 0.6 0.80 5 0,52 0.64 1.2:1. PRE-DEV C= 0.20 10 0.64 0.66 1.53 25 0.78 0.64 1.82 STORM A= 0.78 so 0.92 0.66 2.20 B== 0.64 100 1.01 0.67 2.45 STORM INTENSITY= 1.82 IN/HR PRE-DEV Qp= 0.95 CFS POST-DEVELOPMENT BASIN AREA PRE= 2.6 AC POST-DEVTc= 10.0 MIN POS'r-DEV C= 0.75 STORM INIENSITY= 2.46 IN%HR POST-DEV Qp= 4.79 CF5 H'\1086\009\ROCS\DESIGN\STORM\Basin 211-25yr.xls 1 OF 1 PRINTED: 3/13/2017 GEI#: 1.086.009 DATE: 3/9/2017 ENGINEER: Joel Horn BASIN OS-A& Site - 100Yr NESIS MODIFIED RATIONAL METHOD ISIGINEERING, INC Qp=CiA PRE-DEVELOPMENT RAINFALL FREQ= 100 YR(DURATION 1) 1=A»(Tc/60) " (CITY OF BOZEMAN) BASIN AREA PRE 2.6 AC STORM EVENT STORM 1 COEFF INTENSITY YR A B (IN MR) PRE-DEV'fc= 16.0 MIN 2 -0.36 0.6 0.80 5 0.52 0.64 1.'l.l PRE-DEV C= 0.20 10 0,64 0.66 1 53 25 0.78 0.64 1.82 STORM A= 1.01 50 092 0.66 2.20 B= 0.67 1,00 1.01 0.67 2.45 STORM INTENSITY= 2.45 IN/HR PRE-DEV Qp= 1.27 CFS POST-DEVELOPMENT BASIN AREA PRE= 2.6 AC POST-DEVTC= 10.0 MIN POST-DEV C= 0.75 STORM INTENSITY= 3.:35 IN/HR POST-DEV Qp= 6.54 CFS H 11086\009\DOCS\DESIGN\STORM\Basin all-100yr As 1 OF 1 PRINTED 3/13/2017 Culvert Calculator Report exist `I5" Solve For:Discharge Culvert Summary Allowable HW Elevation 5.80 ft Headwater Depth/Height 1.60 Computed Headwater Eiew 5,80 ft Discharge 6.65 cfs Inlet Control HW Elev. 5.80 ft Taiiwater Elevation 3.30 ft Outlet Control HW Elev. 5.71 ft Control Type Inlet Control Grades Upstream Invert 3.80 ft Downstream Invert 2.80 ft Length 100.00 ft Constructed Slope 0.0110000 ft/ft Hydraulic Profile Profile Oe� S2 Depth, Downstream 0.97 ft Slope Type Steep Normal Depth 0.97 ft Flow Regime Supercritical Critical Depth 1.04 ft Velocity Downstream 6.49 ft/s Critical Slope 0,008835 ft/ft S ecti on Section Shape Circular Mannings Coefficient 0,012 Secftnrtigdt�YiWDPE(Smooth Interior) Span 1.25 fit Section Size 15 inch Rise 1.25 ft Number Sections 1 Outlet Control Properties Outlet Control HW Elev. 5,71 ft Upstream Velocity Head 0.58 ft Ke 0.50 Entrance Loss 0.29 ft Inlet Control Properties Inlet Control HW Elev. 5.80 ft Flow Control Submerged Inlet Type Square edge w/headwall Area Full 1.2 ftz K 0.00980 HDS 5 Chart 1 M 2.00000 HDS 5 Scale 1 C 0.03980 Equation Form i Y 0.67000 Title:McChesney Project Engineer:Jeremy May h:\1086\009\does\design\storm\15hdpe,cvm CUlvertMaster v3.3[03.03.00.04] 03/13/17 08:18:11 Alves Bentley Systems.Inc. Haestad Methods Solution Center Watertown,CT 06795 USA +1-203-755-1666 Page 1 of 1 Cross Section for Catch Gutter Project Description Solve For Discharge Input Data Channel Slope 0.00500 ft/ft Discharge 4.99 ft'/s Gutter Width 1.50 ft Gutter Cross Slope 0.06 ft/ft Road Goss Slope 0.04 ft/ft Spread 5.40 ft Roughness Coefficient 0.012 Crass Section Image 0 38 ft i 0.4C,fit H: t Bentley Systerns,lne. Haestad Methods S aster V8i(SELECTseries 1) [08.11.01.031 3/11/2017 1:35:50 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page 1 of 1 earkshee# for North Swale V Project Description Friction Method Manning Formula Solve For Discharge Input Data Roughness Coefficient 0.030 Channel Slope 0.01000 ft/ft Normal Depth 1,00 If Left Side Slope 4.00 ft/ft(H:V) Right Side Slope 4.00 ft/ft(H:V) Bottom Width 0.00 ft Results Discharge 12.23 ft/s Flow Flow Area 4.00 ft2 Wetted Perimeter 8,25 ft Hydraulic Radius 0.49 ft Top Width 8.00 ft Critical Depth 0.90 ft Critical Slope 0.01784 ft/ft Velocity 3.06 ft/s Velocity Head 0.15 ft Specific Energy 1,15 ft Froude Number 0,76 Flow Type Subcritical GVF Input Data Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 ft Profile Description Profile Headloss 0,00 ft Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Normal Depth 1.00 ft Critical Depth 0.90 ft Channel Slope 0.01000 ft/ft Bentley Systems,Inc. Haestad Methods SoRdidlef.&d rMasterWi(SELECTseries 1) [08.11.01.033 3/13/2017 9:04:58 AM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203.755-1666 Page 1 of 2 Worksheet for North Swale GVF Output Data Critical Slope 0.01784 f/ft Bentley Systems.Inc. Haestad Methods SoH&dlefFtd Master V$i(SELECTseries 1) (08.11,01,03] 3/13/2017 9:04:58 AM 27 Siemens Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 2 of 2 orkshee# for WEST PIPE Project Description Friction Method Manning Formula Solve For Full Flow Capacity Input Data Roughness Coefficient 0.010 Channel Slope 0,01710 fUft Normal Depth 1.00 ft Diameter 1.00 ft Discharge 6.06 ft'/s Results Discharge 6.06 ft'/s Normal Depth 1.00 ft Flow Area 0.79 fta Wetted Perimeter 3.14 ft Hydraulic Radius 0,25 ft Top Width 0.00 ft Critical Depth 0.96 fit Percent Full 100.0 % Critical Slope 0.01486 ft/ft Velocity 7.71 ft/s Velocity Head 0.92 ft Specific Energy 1.92 ft Froude Number 0.00 Maximum Discharge 6.51 ft3/s Discharge Full 6.06 ft/s Slope Full 0.01710 fUft Flow Type SubCritical GVF Input Data Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0,00 ft Profile Description Profile Headloss 0.00 ft Average End Depth Over Rise 0.00 % Bentley Systems,Inc. Haestad Methods ScIhAliblegMicbWaster V8i(SELECTseries 1) 108.11.01.031 3/11/2017 1:43:02 PM 27 Siernons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 1 of 2 Worksheet for WEST PIPE GVF Output Data Normal Depth Over Rise 100.00 % Downstream velocity Infinity ft1s Upstream Velocity Infinity ft/s Normal Depth 1.00 ft Critical Depth 0.96 ft Channel Slope 0.01710 ft/ft Critical Slope 0.01486 ft/ft Bentley Systems,Inc. Haestad Methods SdBatiblookbWaster V8i(SELECTseries 1) (08.11.01.03] 3111/2017 1:43:02 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 2 of 2 €rrksheet for south swale Project Description Friction Method Manning Formula Solve For Discharge Input Data Roughness Coefficient 0.030 Channel Slope 0.01000 ft/ft Normal Depth 0.50 ft Left Side Slope 4.00 ft/ft(H:V) Right Side Slope 4,00 ft/ft(H:V) Results Discharge 1.93 ft is Flow Area 1.00 ft2 Wetted Perimeter 4.12 ft Hydraulic Radius 0.24 ft Top Width 4,00 ft Critical Depth 0.43 ft Critical Slope 0.02282 ft/ft Velocity 1.93 ft/s Velocity Head 0,06 ft Specific Energy 0.56 ft Froude Number 0.68 Flow Type Subcritical GVF Input Data Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Normal Depth 0,50 ft Critical Depth 0.43 ft Channel Slope 0.01000 ft/ft Critical Slope 0.02282 fUft Bentley Systerns,Inc. Haestad Methods S 0kt&Naster V8i(SELECTseries 1) 108.11.01.03] 3/11/2017 1:39:17 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 1 of 1 ®r•ksheet for sidwralk chase Project Description Friction Method Manning Formula Solve For Discharge Input Data Roughness Coefficient 0.012 Channel Slope 0.02000 ftfft Normal Depth 0,50 ft Bottom Width 1,00 ft Results Discharge 3,47 ft'/s Flow Area 0.50 ft' Wetted Perimeter 2.00 ft Hydraulic Radius 0.25 ft Top Width 1.00 ft Critical Depth 0.72 ft Critical Slope 0.00770 ft/ft Velocity 6.95 ftls Velocity Head 0.75 ft Specific Energy 1.25 ft Froude Number 1.73 Flow Type Supercritical GVP Input Data Downstream Depth 0.00 ft Length 0.00 ft Number Of Steps 0 CVP Output Data Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Downstream Velocity Infinity ft/s Upstream Velocity Infinity ft/s Normal Depth 0.50 ft Critical Depth 0,72 ft Channel Slope 0.02000 ftfft Critical Slope 0.00770 ft/ft Bentley Systerns,Inc, Haestad Methods S asterU8i(SELECTseries 1) [08.11.01.03] 3/11/2017 1:40:01 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 1 of 1 orksheef for Curb Inlet Pipe Project Description Friction Method Manning Formula Solve For Full Flow Capacity Input Data Roughness Coefficient 0.010 Channel Slope 0.01710 ft/ft Normal Depth 1.00 ft Diameter 1.00 ft Discharge 6.06 ftyls Results Discharge 6.06 ft'!s Normal Depth 1.00 ft Flow Area 0.79 ft' Wetted Perimeter 3.14 ft Hydraulic Radius 0.25 ft Top Width 0.00 ft Critical Depth 0.96 ft Percent Full 100.0 % Critical Slope 0.01486 fUft Velocity 7.71 ft/s Velocity Head 0.92 ft Specific Energy 1.92 ft Froude Number 0.00 Maximum Discharge 6.51 ft'!s Discharge Full 6.06 ft'/s Slope Full 0.01710 ft/ft Flow Type SubCritical GVF Input Data Downstream Depth 0.00 It Length 0.00 ft Number Of Steps 0 GVF Output Data Upstream Depth 0.00 ft Profile Description Profile Headloss 0.00 ft Average End Depth Over Rise 0.00 % Bentley Systems,Inc. Haestad Methods S olixt rMaster V8i(SELECTseries 1) [08.11,01,03] 311 11201 7 1:41:17 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06796 USA +1-203-755-1666 Page i of 2 ter° sheet for Curb Inlet Pipe GVF Output Data Normal Depth Over Rise 100.00 % Downstream Velocity Infinity fUs Upstream Velocity Infinity ft/s Normal Depth 1.00 ft Critical Depth 0,96 ft Channel Slope 0.01710 ft!ft Critical Slope 0.01486 ft/ft Bentley Systems,Inc. Haestad Methods S aster V8i(SELECTseries 1) (08.11.01,031 3/1V2017 1:41:17 PM 27 Siemons Company Drive Suite 200 W Watertown,CT 06795 USA +1-203-755-1666 Page 2 of 2 The City of Bozeman's Stormwater Division, by Chapter 40 Article 4 oft e it 's Code of Ordinances, approved an Erosion and Sediment Control Permit the Project at 623 Nikles Dr. on 4/17/2017 Direct questions or -report site issues to the Stormwater Division at (406)582-2270. Post this noticeon-site during all construction activities. Plan approved by: Frank Greenhill ®ate: 4/17/2017 —----------- 01 T Erosion and Sediment Control Stormwater Division P.O. Box 1230 Construction Permit Bozeman,Montana 59771 (406)582-2270 Projects Less than I Acre All multi-family, commercial, Utility, demolition, and paving projects less than one acre are required to submit this application and receive an approval letter before initiating construction activities.The City of Bozeman's agent will review, determine adequacy, inspect, and enforce all provided information. Failure to meet City of Bozeman's requirements will result in violations and enforcement action consistent with the City's Municipal Code and Enforcement Response Plan (ERP). There is no fee associated with this permit.This plan is active upon approval and terminated upon the receipt of a Certificate of Occupancy. ct,ori —Applicant Information 1. Preparer: Jeremy May Company: Genesis Engineering Inc. Phone: 406-581-5730 Email: jmay@g-e-i.net 1 Ad d ress:204 North 11 th Ave I City:Bozeman State:MT .......J Zip code:59715 2. Owner:Dan Barnes Company:Longshot Equity LLC Phone:(406)581 -0667 Y Email: Address:1871 South 22nd Ave. Suite I I City,Bozeman State:MT Zip code.59718 .......... —---------- 3. Contractor: TBD ------ Company: ..........-------------------- --------- .............—--—------- Phone: Email: Address: City: JState: Zip code: Section 2—Project Information Project Name:McChesney Business Center Total Land Disturbance:0.97 ACRES Project Address:623 Nikles Drive.Bozeman,MT 59715 _J Project Type:Work/Live Units Section 3—Project Schedule Start Date:May 1st,2017 Final Sia6ihzation Date:Dec 2018 1. Applicant must provide a site map(s)that includes the following: FV1 Project boundary [a Direction(s)of stormwater run on and run off FVJ Public and private stormwater infrastructure on or adjacent to site F7J Material storage area(s) F/I Equipment staging area(s) BMPs selected in Section 5 ................ ........ .............. .............. ................. ---------- ..................... ................... ---------- �Section 5—Required Stormwater Controls **Use the City of Bozeman's Best Management Practice (BMP) Manual to select required controls." 1. Protect inlets: Inlets receiving site runoff require BMPs that filter stormwater before flowing into underground infrastructure. Check all that apply and show location(s) on rnap. Approved options include: F]Pre-Manufactured Drop Inlet Protection (pg. 13) FV-]Rock Sock Inlet Protection (pg. 13) F�Not Applicable (describe): Fv�Other: "Continued on next page** 2. Contain disturbed areas: Project boundaries require BMPs that contain stormwater flowing from disturbed areas. Check all that apply and show location(s)on map.Approved options include: F,-/]Silt Fence (pg. 9) ®Earthen Berm (pg. 11) [71Straw Wattle (pg. 7) 1 ❑Not Applicable F.710ther: EXISTING GRADE BARRIERS 3. Mitigate tracking- Exit points require BMPs that prevent the tracking of debris off-site onto the right-of-way. Check all that apply and show location(s)on map.Approved options include: [Cobble/Cattle Guard Hybrid Track Pad (pg. 15) QAngular Rack Track Pad (pg. 15) F-1 Not Applicable(describe):_ [-,/�Other: THE EXCAVATION COMPANY WILL HAVE TO SWEEP PAVEMENT FOLLOWING MOBILIZATION OF EQUIPMENT. 4. Control concrete waste:Concrete activities require BMPs that allow for the capture and disposal of generated pollutants to prevent environmental contamination. Check all that apply and show location(s)on map.Approved options include: [Reusable or Disposable Product (pg. 22) [Prefabricated Roll-Off(pg. 22) F7JBelow Ground Containment(pg. 23) ❑Above Ground Containment(pg. 23) ❑Not Applicable(describe): [Other: 5, Contain material stockpiles: Material stockpiles, not already contained within an existing perimeter control, require perimeter BMPs that prevent erosion and displacement of loose material. Check all that apply and show location(s) on map.Approved options include: [Earthen Berm (pg. 11.) [Silt Fence(pg. 9) MStraw Wattle (pg. 7) [:1 Cover/Tarp F-1 Existing Perimeter Control BM P (#1) [Not Applicable(describe):__ P/1Other: Compaction/Tracking of piles&other silt fence or wattle, **Continued on next page** .............. ................'............ ........... ........................ 6. Manage clewatering flows: Pumping activities require BMPs that filter water before entering underground infrastructure or waterways. Check all that apply and show location(s) on map Approved options include: F,-/]Excavated Area Dewatering Plan (pg, 19) F-1Well Dewatering Plan (pg. 20) ❑Not Applicable(describe):__ F10ther: 7. Protect post-construction stormwater features: Post-construction stormwater features, such as retention and detention ponds, require BMPs that protect and their silde slopes and bases during and after construction activities. Check all that apply and show location(s) on map.Approved options include: RCrimped Straw Mulch (pg. 24) R Rolled Erosion Control Products (pg. 24) [ Rip Rapped Inlet and Outlet [Check Darns R Reinforced Fore Bay Not Applicable (describe):ALL DISTURBED AREAS WILL HAVE SOD OR HARDSCAPE LANDSCAPING. 0 t h e r: 8. Stabilize disturbed areas: Disturbed areas require BMPs that prevent erosion of barren ground. Check all that apply and show location(s)on map. Approved options include: RSurface Roughening(pg. 24) Rcriniped Straw Mulch (pg. 24 RWood Mulch( pg. 24) R Rolled Erosion Control Products (pg. 24) RV Sod (pg. 24) E]Not Applicable Rother: Section 6—Administrative and Operational Controls 1.Check which of the following will be utilized and show on the map if applicable: R,/ Street Sweeping--Frequency:AS BUILDUP OCCURS On-Street Parking ❑Pedestrian and Traffic Control Fencing ❑Covered Pollutant Storage RV Staked Sanitary Facility out of Right-of-Way **Continued on next page** Authentisign ID:240D48DE.A95E.45B4-B570-6A5714884894 Section 7-Certifications 1.Applicant agrees to: o Install applicable BMPs before the start of land disturbing activities. Initial: C'J o Keep this permit posted on-site and updated to reflect current site conditions.Initial:CC b o Inspect and maintain all control measures at the end of each workday. Initial: `b o Contain and dispose of all pollutants generated,such as form oil,oils/greases,fuel,masonry wash water, concrete cutting slurry,asphalt sealant,paint,and all other pollutants hazardous to the environment, by local, state and federal regulations.Initial: -'� o Maintain a spill kit on-site,which includes,at a minimum,absorbent material,cleanup tools,and covered waste container.Initial:d b Section 8—Acknowled ment Certificate I certify that I am the Owner or Owner's Authorized Agent. If acting as an Authorized Agent,I further certify that I am authorized to act as the Owner's Agent regarding the property at the above-referenced address for the purpose of filing applications for decisions,plans,or review under the City of Bozeman Ordinance#1763 and have full power and authority to perform on behalf of the Owner all acts required to enable the City to process and review such applications.I certify that the information on this application is true and correct and understand that I shall not start this project until this application is approved.I shall comply with the laws of the State of Montana and the Ordinances o k0ga Bozeman. Signature of Legally Responsible Person Date a��ll C �rne 0�y��er Printed Name Title x jo >s Y � z o r ' r f i I�ba'`1'1.� � 1 '♦' )-� rJ pr��a uu l cs r- � y it i" 2 7 1I 'I" i Alool Ll— T y. to f> z r a u I ! 1 f ¢LD i ....__. es ._......._..�...._�. :: _ ..... 5 cD O I ( ,JA W 1 X?N 2 I tif� �! N i I a z # d aq§ z a C / GrV. ♦ i � ...� i �� z �l I �=w 7 7 Y � t UJ pf? c7 c Spit ,, � y � s 3 - ]4 i r+ Y! O y i ➢ t;J,a u k a. I � f � �- f i '., � �qE`a 1[L65 YNVtWt7W"TltlW32Otl � 1 4 4 er I qd� nk` oFtcxoa od-atv#u aor �yrw»u�a.� �ixi3 u oa NOilttJ{dl?3ds -. 1 3 � Iff fi` f� ``I �F� N61S'U4I�Y314MWNCitS WiN:NMYN(t { Nt1W3209JOA1133NL eYartttfv:uvn ` 1 rm Al + u / I Northbound Lofts NB Lofts Condo Association Appendix A Storm Water Facilities Operation & Maintenance Manual Overview The HOA is responsible for maintaining all of the onsite Storm Water Facilities,including storm inlets,storm pipe and the storm water detention pond per the schedule below. Maintenance The storm inlets and pond outlet structure are to have the sediment removed from the sediment traps on a yearly basis or an updated maintenance schedule as determined by monitoring the sediment build-up of the inlets quarterly. The storm pipe between the storm inlets is to be monitored yearly for build-up of sediment or trash. If the storm system is operating correctly the build-up should be minimal and therefore maintenance schedule will be directly correlated to the yearly inspection findings. The storm water detention pond shall be monitored every five years for sediment build-up. When the sediment build- up starts to decrease the capacity of the detention pond the sediment shall be removed mechanically and hauled from the site. It the extraction of the sediment removes the vegetation from the bottom of the pond, it should be reseeded or re-sodded and appropriate storm water BMPs are to be installed until the vegetation is stabilized. See the maintenance agreement with Lots 17A, 21A and 22 as filed at the Gallatin County Clerk and Recorders for information regarding maintenance of the offsite pipe and manholes that convey storm water from this site. Contact Information Property Manager: Association President: