Loading...
HomeMy WebLinkAbout008_MasterStormDrainagePlan Submitted: April 5, 2021 Revised: October 20, 2021 Revised: February 1, 2022 Project No. 17055 MASTER STORM DRAINAGE PLAN FOR GLEN LAKE ROTARY PARK OVERVIEW NARRATIVE The purpose of this drainage plan is to quantify storm drainage improvements required for the proposed construction activities at the Glen Lake Rotary Park in Bozeman, Montana. The site is located north of Griffin Drive and east of Manley Road. The park is currently a recreation area with a beach, volleyball fields, a climbing rock, bathrooms, numerous trails, and a gravel parking lot. The approximately 30-acre park will be improved with a new paved parking lot, an access road, and a multi- use path. According to the project’s Master Site Plan, the phasing sequence for all the public improvements at the Glen Lake Rotary Park is planned in the following three phases: Phase 1—South Section—56,000 SF Phase 2—Middle Section—32,000 SF Phase 3—North Section—88,000 SF This Master Storm Drainage Plan presents a summary of calculations performed to quantify the stormwater runoff for the improved site. A separate stormwater report will be provided for each individual phase. All design criteria and calculations are in accordance with The City of Bozeman Design Standards and Specifications Policy (DSSP), dated March 2004. The site stormwater improvements have been designed with the intent to meet the current City of Bozeman drainage regulations for the entire project to the extent feasible. Project Information This site is located on COS 1221, Tract GL2, T 1S R6E S 31. There is no formal physical address for this project location. V:17055_Storm_Drainage_Plan.docx 2 (2/1/22) SH/rrr/ed The entire park area is approximately 29.8 acres. However, only the area hydrologically associated with the proposed improvements will be analyzed. The disturbed area associated with the new parking lot, access drive, and multi-use path will be analyzed for stormwater treatment, and this area accounts for 4.24 acres. An additional 0.22 acres of unimproved area runs on to the proposed improvement area. The final discharge point for this 4.46 acres is the northeast corner of the park to an existing vegetated ditch that eventually discharges to the East Gallatin River. The area analyzed under pre-development conditions, 3.44 acres, represents the area that currently drains to the existing vegetated channel. The other improvements on the site add a negligible amount of impervious area since the improvements are separated by pervious area. The existing impervious area outside of the parking lot, access drive, and multi-use path will not be included in the analyzed area. Surface Pre- development acres Post- development acres Impervious 0.00 1.97 Gravel 0.54 0.20 Pervious 2.90 2.29 Total 3.44 4.46 HYDROLOGY The Rational Method and rainfall data provided in The City of Bozeman DSSP was used to calculate the runoff volumes for the 10-year, 2-hour storm event for the runoff storage facilities (water quantity), and the peak flows from the 25-year storm event were used for the storm drain conveyance facilities. Watersheds were delineated for both existing and proposed conditions, which are shown in Exhibits A and B in Appendix A. The weighted runoff coefficient “C” was calculated for each contributing area using 0.95 for impervious areas, 0.80 for gravel areas, and 0.30 for grassed and adjacent pervious areas. The runoff treatment flow rate for the first 0.5-inch storm event was calculated using the equations below. The results of the hydrologic analysis for the storm events described above are shown in Appendix B. The overall drainage plan includes 11 watersheds. Phase 3 includes Watersheds 1-7, Phase 2 includes Watersheds 8 and 9, and Phase 1 includes Watersheds 10 and 11. The figures showing the watershed delineations for pre- and post-development conditions are included in Appendix A. Detailed calculations for both the pre- and post-development basins is provided in Table 1 and 2 of Appendix B. As described above, the project will be broken up into three Phases. However, each Phase is hydrologically connected to each other. Phase 3 is the most downstream and the location of the final discharge location. Phase 1 drains into Phase 2, which drains into Phase 3. The time of concentration for each Phase for existing conditions was calculated to determine the peak pre-development for rate for each phase, and detailed calculations have been provided in Appendix B. The pre-development peak flow rate is used as the design release rate for calculating the required storage volume. V:17055_Storm_Drainage_Plan.docx 3 (2/1/22) SH/rrr/ed Hydrologic Equations Q = Cwd x I x A Cwd = Weighted Runoff Coefficient A = Area (acres) I = Rainfall Intensity (in/hr) associated with Calculated Time of Concentration Q = Peak Runoff (cfs) Watersheds Area (acres) Total Time of Concentration (min) 10-Year Storm Intensity (in/hr) 10-Year Storm Peak Pre- Development Flow (ft3/s) Existing Phase 1 1.57 36.93 0.88 0.46 Existing Phase 1 & 2 2.67 41.71 0.81 0.81 Existing Phase 1, 2 & 3 3.44 46.15 0.76 0.93 Hydraulic Design In general, the storm drain design consists of storm drainage chases that will drain the runoff from the parking lot and into a new ditch located along the eastern edge of the new parking lot. A watershed was delineated to each drainage chase to calculate the required capacity of the new ditch. The ditch will direct runoff into a new basin at the northeast corner of the park. The basin will outfall into the existing vegetated channel that runs along the east side of the park. This channel eventually outfalls into the East Gallatin River. The ditch cross section side slopes vary to maintain a positive longitudinal slope and tie into the proposed gravel sidewalk along the parking lot and the existing slope to the east. The fill slope off the edge of the proposed gravel sidewalk is 4:1 for 6.5 feet providing a 1.625 feet minimum ditch depth. Except for the very end of the ditch, the ditch depth was increased to 1.80 feet. The back slopes range from 4:1 to 2:1, where 2:1 side slopes are used to avoid encountering the landfill area located just east of the new ditch. The ditch conveyance capacity was calculated using Bentley’s FlowMaster, which applies the Manning’s Equation to determine the capacity of the ditch based off the longitudinal slope, side slopes, Manning’s Roughness, and depth. A Manning’s Roughness coefficient of 0.03 was used to determine the ditch capacity. The smallest ditch capacity for each watershed was compared to the 25-year, 5-minute peak flow to determine if the ditch can adequately convey the runoff. Throughout the length of the ditch, there are gravel paths that perpendicularly cross the ditch to connect the new gravel sidewalk along the new parking lot to the existing trails to the east of the project. Reinforced concrete culverts will be used to convey the ditch under the gravel paths, the culverts will range between 12 and 18 inches in diameter. The Federal Highway Association HY 8 program was used to calculate the conveyance capacity of the culverts and the headwater depth at peak flow. The culverts were sized to adequately convey the peak flow rates from the 25-year storm event without overtopping, and it was confirmed the ditch depths are greater than the peak flow headwater depth. V:17055_Storm_Drainage_Plan.docx 4 (2/1/22) SH/rrr/ed For calculating the total peak flow to the ditch sections and culverts, a conservative time of concentration of 5 minutes was used. The table below compares the calculated peak flow rates to the capacity of each hydraulic feature (ditch or culvert). Phase Watershed Area (sf) Q25 Peak Flow (cfs) Curb Chase Capacity Downstream Feature Cumulative Peak Flow Q25 (cfs) Ditch Capacity (cfs) Culvert Capacity (cfs) 25-year Headwater Depth at Peak Flow (ft) 3 1 14,880 1.11 2.850 Permanent Basin 1.11 Pond - - 3 2 16,167 1.08 - Permanent Basin 4.14 Pond - - 3 3 12,863 1.05 2.850 WS 2 1.05 1.48 - - 3 4 7,259 0.26 2.850 WS 2 0.26 1.48 - - 3 5 8,499 0.64 - WS 2 0.64 1.48 - - 3 6 15,741 1.12 2.850 Permanent Basin 8.81 30.74 8.92 (18-inch) 1.77 3 7 11,472 0.98 2.850 WS 6 7.68 26.49 - - 2 8 25,048 1.61 2.850 WS 7 6.70 20.93 - - 2 9 21,028 1.42 2.850 WS 8 5.09 33.43 - - 1 10 31,461 2.05 2.850 Phase 1: Temp Basin Phase 2: WS 9 3.68 63.45 4.17 (12-inch) 1.37 1 11 29,868 1.63 2.850 WS 10 1.63 115.11 4.10 (12-inch) 0.77 WATER QUANTITY AND QUALITY DESIGN Water Quantity – Flood Storage Water Quantity Volume: Q (cfs) = Cwd x 10 – Year Intensity in/hr x Area (acre) V (cf) = Duration (sec) x QPost (ft3) – Duration (sec) x Qpre(ft3) V (cf) = Required Storage Volume The required flood storage volume, referred to as the water quantity volume, was determined using the Rational Method for the 10-year, 2-hour design storm. The pre-development peak flow rate is used as the design release rate for calculating the required storage volume. Each storm duration for the 10-year storm event is analyzed to determine the which storm duration produced the largest runoff volume. The largest runoff volume is the minimum required storage volume needed for the project. The table below summarized the required storage volume for each phase, Appendix D provides the detailed calculations for each Phase. V:17055_Storm_Drainage_Plan.docx 5 (2/1/22) SH/rrr/ed Phase 1 and Phase 2 do not have adequate area for detention basins. A temporary basin will be constructed for Phase 1 to detain runoff to limit the peak discharge rate to the pre-development flow rate. A circular orifice with a 4-inch diameter was designed to restrict the peak flow to 0.46 cfs. The orifice structure has a 12-inch RCP inlet and outlet pipe, with a 1% slope and the capacity to pass the 25-year storm event. The outlet pipe discharges into the existing vegetated channel along the edge of the existing gravel drive. The permanent detention basin for the entire project will be constructed at Phase 2 and will be large enough to detain the required volume for all three Phases. The bioswale to the permanent detention basin will also be constructed with Phase 2. The orifice structure and outfall pipe constructed in phase 1 will be moved and utilized at the permanent detention basin to limit the peak discharge rate to the pre-development flowrate for phases 2 and 3. The inlet and outlet pipe slopes will be reset to be oversized for phase 2 to have capacity to pass the 25-year storm for phase 3. The orifice diameter will be adjusted between phases to adjust the allowable peak discharge rate between Phases 1, 2, and 3. At Phase 2, the opening will be cut to 5.3-inches to reduce the discharge peak flow rate to 0.81 cfs. The outfall pipe slope will be set to 12%, and riprap will be installed at the outlet. At phase 3, the orifice diameter will be cut to have a 5.7-inch diameter, and the outfall pipe slope will remain. Watersheds Area (acres) Provided Storage Location (ft3) 10-Year Storm Required Storage (ft3) Provided Storage (ft3) Pre- Develop. Peak Flow Rate (cfs) Orifice Capacity (cfs) 25- Year Peak Flow (cfs) Outfall Pipe Capacity (cfs) Proposed Phase 1 1.41 Temporary Basin at the downstream end of Phase 1 683.82 2,466 0.46 0.46 3.68 4.05 Proposed Phase 1 & 2 2.47 Permanent Basin within Phase 3 1,270.39 3,200 0.81 0.81 6.7 13.37 Proposed Phase 1, 2 & 3 4.46 Permanent Basin within Phase 3 3,237.50 3,239 0.93 0.93 12.94 13.37 Water Quality Due to high groundwater within the park, treating the runoff via infiltration is not feasible. An exhibit of the piezometric contours is provided in Appendix E. Biofiltration swales are used to treat the runoff from the first 0.5-inch storm event for most of the project area. Watershed 1 and 2 within Phase 3 will utilize the proposed permanent detention basin for treatment. The calculations provided in the DSSP were used to determine if the detention basin had adequate area to settle the suspended solids. Detention Basin: V:17055_Storm_Drainage_Plan.docx 6 (2/1/22) SH/rrr/ed The detention basin will only need to treat the runoff from Watershed 1, 2 and 6 since the other basins are treated via the biofiltration swales. The basin area was calculated to release the runoff at a rate less than 145-square feet per 1-cfs for sediment control to treat the runoff. The settling velocity of 40 micron particles is 0.0069 fps allowing sediment to settle and treat the runoff before discharge. Based on the calculations below, the basin is adequately sized to treat the runoff by allowing sediment to settle. Phase 2: Design Release Rate = 0.81 cfs Minimum Area Required =0.81 cfs ÷ 0.0069 ft/sec = 117 sf Provided 735 sf > 117 sf Water Depth = 1.5 feet Volume = 3,239.83 Phase 3: Design Release Rate = 0.93 cfs Minimum Area Required =0.93 cfs ÷ 0.0069 ft/sec = 134 sf Provided 735 sf > 134 sf Water Depth = 1.5 feet Volume = 3,239.83 Biofiltration Swale: The calculations outlined in the Montana Post-Construction Stormwater BMP Design Guidance Manual from Chapter 3 were used to calculate the Runoff Treatment Flow Rate (RTF). These calculations are provided in Appendix D. The table below summarizes the RTF, required swale length and provided swale length for each watershed. The associated calculations for the biofiltration swale and design assumptions are provided below. Phase WS Area (ft2) % IC RTF (cfs) Long. Slope (ft/ft) Bottom Width (ft) Min. Side Slope (z:1) Wetted Area (ft2) Velocity (ft/sec) Required Ditch Length (ft) Provided Ditch Length (ft) 3 1 14,880 59% 0.082 0.005 0.72 4.00 0.75 0.11 Permanent Detention Pond 3 2 16,167 47% 0.070 0.005 0.47 4.00 0.75 0.09 3 3 10,462 84% 0.080 0.005 0.69 4.00 0.75 0.11 58 59 3 4 7,259 4% 0.001 0.005 -0.99 4.00 0.75 0.00 1 N/A 3 5 8,499 60% 0.047 0.005 0.00 4.00 0.75 0.06 34 50 3 6 15,741 46% 0.066 0.006 0.26 3.00 0.69 0.10 51 107 3 7 11,472 68% 0.072 0.006 0.38 3.00 0.69 0.11 56 109 2 8 25,048 38% 0.086 0.004 1.03 2.00 0.63 0.14 75 213 2 9 21,028 44% 0.084 0.006 0.61 2.00 0.63 0.13 72 144 1 10 31,461 41% 0.117 0.015 0.92 2.00 0.63 0.19 101 223* 1 11 29,868 28% 0.071 0.008 0.69 2.00 0.63 0.11 62 138 V:17055_Storm_Drainage_Plan.docx 7 (2/1/22) SH/rrr/ed *At Phase 1, the new ditch/biofiltration swale will not be entirely constructed and will only provide 53 feet of length upstream of the temporary detention basin. However, runoff will outfall into the existing vegetated channel which is 385 feet in length within the park property limits which will adequately treat the RTF. Bottom Width: The bottom width of the biofiltration swale was calculated using the Manning’s Equation. The calculation to determine the bottom width of the swale result in a bottom width of less than 2-feet. A minimum bottom width of 2-feet is required for biofiltration swales, therefore a bottom width of 2-feet has been provided for the swale. Bottom Width Equation b = n × RTF1.49 y × s − z × y RTF = Runoff treatment design flow rate (cfs) s = Longitudinal Slope of the swale (ft/ft) n = Manning’s Coefficient b = Bottom width of the swale (ft) z = Side Slope of the swale in the form of z:1 y = Design flow depth for RTF (ft) Longitudinal Slope: The longitudinal slope varies between 1.8% and 0.67%. to construct a ditch that maintains positive flow and has adequate depth. The recommended longitudinal slope is 1.5%, however, due to the high groundwater of the site and to keep import fill costs down, a minimum longitudinal slope of 0.67% is provided. Manning’s Coefficient: Table 5.6-1 from the Montana Post-Construction Storm Water BMP Design Guidance Manual outlines flow resistance coefficients for various vegetation and soil conditions. A Manning’s Coefficient of 0.22 was chosen for grass legume mix on lightly compacted topsoil. Side Slope: The side slope varies between 10:1 and 2:1 to tie into the new gravel path and existing ground to the east of the ditch. It is recommended that side slopes be no steeper than 3:1, however due to the proximity to the Bozeman City Landfill, 2:1 side slopes for the connection to the existing ground east of the park is use to avoid encountering landfill material. Design Flow Depth: A design flow depth of 3 inches was assumed since the swale will be seeded with primarily dryland grasses per Section 5.6.4.4 Velocity: The maximum allowable runoff treatment design flow velocity is 1 ft/section. V:17055_Storm_Drainage_Plan.docx 8 (2/1/22) SH/rrr/ed V = RTF A A = y (b + yz) V = Flow velocity at RTF (ft/sec) A = Wetted Area (sq. ft.) RTF = Runoff treatment design flow rate (cfs) L = Vt 60 min sec L = Swale length (ft) V = Flow velocity at RTF (ft/sec) t = Hydraulic residence time t = The hydraulic residence time is set to a minimum allowable time of 9 minutes. L = The minimum recommended length of a swale is 100 feet. The biofiltration swales for Watersheds 1, 7, 8, 9, 10, and 11 all have a minimum length of 100 feet. Watersheds 2, 3, 5 and 6 do not have minimum lengths of 100 feet. However, lengths exceeding the calculated required lengths have been provided. Watershed 4 is completely pervious and does not require treatment. The biofiltration swales are being used as an online best management practice and have been designed to convey the peak flows from the 25-year storm event at depths greater than the RTF design flow depth of 3-inches. As stated in the City of Bozeman DSSP and the Montana Post-Construction Storm Water BMP Design Guidance Manual, 90 percent of the rainfall events are 0.5 inches or less on average, and the General MS4 permit requires that BMPS are designed to treat the runoff generated from the first 0.5 inches of rainfall from a 24-hour storm preceded by 48 hours of no measurable precipitation. The biofiltration swales will have the capacity to convey the peak flows from a 0.5-inch, 24-hour storm event within the design flow depth of 3-inches. The minimum capacity of the biofiltration swales at a 3-inch depth is 2.21 cfs, and the maximum peak flow for a 0.50 inch, 24-hour storm event for all the watersheds is 0.22 cfs. MAJOR STORM EVENTS For storm events larger than the 25-year storm event, the runoff in the ditch will overtop the new gravel trail and flow in the curb line of the parking lot to the south. Runoff will pond in the parking lot until it can overtop at the north end of the park to the existing vegetated channel. The grading of the new parking lot is sloped to the east/northeast. If runoff was to overtop the ditch banks and into the parking lot, it would stay along the east side of the parking lot and would not flow west toward the new improvements and the Glen Lake Rotary Park. SUMMARY V:17055_Storm_Drainage_Plan.docx 9 (2/1/22) SH/rrr/ed The above calculations show that the stormwater drainage system for the East Gallatin Recreation Improvements meets the requirements of the City of Bozeman DSSP. The Drainage Master Plan is divided into three Phases and 11 watersheds. Runoff from the access drive and parking areas flows through storm drain chases to a ditch running along the eastern side of the project limits. The ditch conveys and treats runoff as a biofiltration swale. The ditch flows to a permanent detention basin at the northern portion of the project within Phase 3. A temporary basin will be installed in Phases 1 to hold excess runoff until Phase 2 completes the ditch connection to the permanent basin at the northern end of the park. An outfall structure will be used to discharge water from the ponds at the pre-development flow rate into the existing vegetated channel. A maintenance plan for the stormwater facilities has been included in the appendix. V:17055_Storm_Drainage_Plan.docx 10 (2/1/22) SH/rrr/ed Appendix A WATERSHED MAPS PHA S E 1 PHA S E 2 PHA S E 2 PHA S E 3 EXHIBIT B NORTH 050 SCALE:1" = 100' 10050 ASPHALT AREA CURB AND GUTTER EDGE OF ASPHALT EDGE OF GRAVEL GRAVEL AREA CONCRETE AREA APPROXIMATE BOZEMAN OLD CITY LANDFILL BOUNDARY CONSTRUCTION LIMITS WATERSHED BOUNDARY V:17055_Storm_Drainage_Plan.docx 11 (2/1/22) SH/rrr/ed Appendix B HYDROLOGY CALCULATIONS Project: Glen Lake Rotary Park Project #: 17055 Date: 10/14/2021 Time of Concentration=5 mins Intensity10-Year, 2-Hr=0.41 in/hr Water Quality=0.5 inches WS Area (sf) Area (ac.) Area Impervious (sf) Area Gravel (sf) Area Pervious (sf) RC % IC Tc (hours) I10 (in/hr) Q10 Peak Flow (cfs) Phase 1 68,235 1.57 0 4,698 63,537 0.33 0% 36.93 0.88 0.46 Phase 1 & 2 116,211 2.67 0 17,101 99,110 0.37 0% 41.71 0.81 0.81 Phase 1, 2 & 3 149,901 3.44 0 17,101 132,800 0.36 0% 46.15 0.76 0.93 PRE-DEVELOPMENT PEAK FLOW RATE CALCULATIONS Project: Glen Lake Rotary Park Project #: 17055 Date: 02/01/2022 Time of Concentration= 5 mins Intensity25-Year, 5-Min= 4.76 in/hr WS Tc (hours) Area (sf) Area (ac.) Area Impervious (sf) Area Gravel (sf) Area Pervious (sf) RC % IC Q25 Peak Flow (cfs) Curb Chase Capacity (cfs) Downstream Feature Cumulative Peak Flow Q25 (cfs) Ditch Capacity at Full Depth (cfs) Culvert Capacity (cfs) 1 0.083 14,880 0.34 8,720 0 6,160 0.68 59% 1.11 2.850 WS 2 1.11 Pond - 2 0.083 16,167 0.37 7,631 193 8,343 0.61 47% 1.08 - Pond 4.14 Pond - 3 0.083 12,863 0.30 8,830 0 4,033 0.75 69% 1.05 2.850 WS 2 1.05 1.48 - 4 0.083 7,259 0.17 306 0 6,953 0.33 4% 0.26 2.850 WS 2 0.26 1.48 - 5 0.083 8,499 0.20 5,068 0 3,431 0.69 60% 0.64 - WS 2 0.64 1.48 - 6 0.083 15,741 0.36 7,195 1,751 6,795 0.65 46% 1.12 2.850 Pond 8.81 30.74 8.92 7 0.083 11,472 0.26 7,759 1,014 2,699 0.78 68% 0.98 2.850 WS 6 7.68 26.49 - Phase 3 0.083 86,880 2.0 45,509 2,958 38,413 0.66 52% 6.24 - Pond 12.94 - - 8 0.083 25,048 0.58 9,635 1,851 13,562 0.59 38% 1.61 2.850 WS 7 6.70 20.93 - 9 0.083 21,028 0.48 9,244 1,276 10,508 0.62 44% 1.42 2.850 WS 8 5.09 33.43 - Phase 2 0.083 46,075 1.06 18,879 3,126 24,070 0.60 41% 3.02 -Phase 3 6.70 - - 10 0.083 31,461 0.72 12,945 1,839 16,677 0.60 41% 2.05 2.850 WS 9 3.68 63.45 4.17 11 0.083 29,868 0.69 8,379 977 20,513 0.50 28% 1.63 2.850 WS 10 1.63 115.11 4.10 Phase 1 0.083 61,329 1.41 21,324 2,816 37,190 0.55 35% 3.68 -Phase 2 3.68 - - POST-DEVELOPMENT PEAK FLOW CALCULATIONS Project: Glen Lake Rotary ParkProject #: 17055Date: 10/14/2021TcL (ft)nP (in)s (ft/ft)Tsf (min)s (ft/ft)V (ft/s)L (ft)Tscf (min)r (ft)s (ft/ft)nV (ft/s)L (ft)Tch (min)Total(min)Existing Phase 1 229 0.150 1.280 0.0138 34.87 0.0101 1.62 201 2.0736.93Existing Phase 1 & 2 229 0.150 1.280 0.0138 34.87 0.0074 1.39 418 5.02 0.333 0.004 0.040 1.07 117 1.82 41.71Existing Phase 1, 2 & 3229 0.150 1.280 0.0138 34.87 0.0074 1.39 418 5.02 0.333 0.004 0.040 1.07 402 6.26 46.15Proposed Phase 1, 2 & 3116 0.150 1.280 0.0138 20.24 0.0200 2.87 85 0.49 0.333 0.006 0.040 1.38 798 9.63 30.36USDA Urban Hydrology for Small Watersheds TR-55 Manual.Sheet Flow Equations Shallow Concentrated Flow Equations Channel/Pipe Flow EquationsEq. 3-3TIME OF CONCENTRATIONWatershedSheet FlowShallow Concentrated FlowChannel FlowTsf0.007(nL)0.8 P20.5s0.4 L = Length of overland sheet flow (ft)n = Manning's roughnessP = 2-year, 24-hour rainfall, ins = Slope (ft/ft) V16.135s0.5for Grassed WaterwaysV6.9620.5for Short-grassed pastureV = 20.3280.5for PavementTscfL60V s = Slope (ft/ft)L = Length of overland sheet flow (ft)V1.49(r0.67s0.5) n TchL60V L = Length of overland sheet flow (ft)n = Manning's roughnesss = Slope (ft/ft) r = hydraulic radius (ft) Project: EGRA Site Improvements Project #: 17055 Date: 6/15/2018 Design Standards and Specifications Policy City of Bozeman, March 2004 as Amended RAINFALL INTENSITY-DURATION CURVES (Figures I-2, I-3) Time 2 5 10 25 50 100 (min)(in/hr)(in/hr)(in/hr)(in/hr)(in/hr)(in/hr) 1 4.20 7.15 9.16 10.72 13.72 15.69 5 1.60 2.55 3.22 3.83 4.74 5.34 10 1.05 1.64 2.05 2.46 3.00 3.35 15 0.83 1.26 1.58 1.89 2.30 2.56 20 0.70 1.05 1.31 1.58 1.90 2.11 25 0.61 0.91 1.13 1.37 1.64 1.82 30 0.55 0.81 1.00 1.22 1.45 1.61 35 0.50 0.73 0.91 1.10 1.31 1.45 40 0.46 0.67 0.83 1.01 1.20 1.33 45 0.43 0.63 0.77 0.94 1.11 1.22 50 0.40 0.58 0.72 0.88 1.04 1.14 55 0.38 0.55 0.68 0.82 0.97 1.07 60 0.36 0.52 0.64 0.78 0.92 1.01 75 0.31 0.45 0.55 0.68 0.79 0.87 90 0.28 0.40 0.49 0.60 0.70 0.77 105 0.26 0.36 0.44 0.55 0.64 0.69 120 0.24 0.33 0.41 0.50 0.58 0.63 150 0.21 0.29 0.35 0.43 0.50 0.55 180 0.19 0.26 0.31 0.39 0.45 0.48 360 0.12 0.17 0.20 0.25 0.28 0.30 720 0.08 0.11 0.13 0.16 0.18 0.19 1440 0.05 0.07 0.08 0.10 0.11 0.12 Storm Recurrence Interval V:17055_Storm_Drainage_Plan.docx 12 (2/1/22) SH/rrr/ed Appendix C HYDRAULIC CALCULATIONS Curb Chase Capacity Calculation HY-8 Culvert Analysis Report Culvert Data: Path Culvert 1+45 Headwater Elevation (ft) Total Discharge (cfs) Culvert 1 Discharge (cfs) Roadway Discharge (cfs) Iterations 4698.85 0.50 0.50 0.00 1 4699.23 1.63 1.63 0.00 1 4699.44 2.40 2.40 0.00 1 4699.72 3.35 3.35 0.00 1 4700.02 4.30 4.14 0.13 22 4700.07 5.25 4.26 0.96 6 4700.11 6.20 4.35 1.83 5 4700.14 7.15 4.42 2.70 4 4700.17 8.10 4.48 3.60 4 4700.19 9.05 4.53 4.49 4 4700.22 10.00 4.59 5.39 4 4700.00 4.10 4.10 0.00 Overtopping Total Discharge (cfs) Headwater Elevation (ft) Inlet Control Depth (ft) Outlet Control Depth (ft) Normal Depth (ft) Critical Depth (ft) Outlet Depth (ft) Tailwater Depth (ft) Tailwater Velocity (ft/s) 0.50 cfs 4698.85 0.39 0.053 0.21 0.29 0.22 0.28 1.56 1.63 cfs 4699.23 0.77 0.400 0.40 0.54 0.42 0.44 2.10 2.40 cfs 4699.44 0.98 0.646 0.49 0.66 0.53 0.51 2.31 3.35 cfs 4699.72 1.26 1.095 0.60 0.78 0.64 0.58 2.51 4.30 cfs 4700.02 1.56 1.373 0.70 0.86 0.74 0.63 2.68 5.25 cfs 4700.07 1.61 1.419 0.72 0.87 0.76 0.68 2.81 6.20 cfs 4700.11 1.65 1.452 0.73 0.88 0.77 0.73 2.93 7.15 cfs 4700.14 1.68 1.479 0.74 0.88 0.77 0.77 3.04 8.10 cfs 4700.17 1.71 1.503 0.75 0.88 0.78 0.80 3.13 9.05 cfs 4700.19 1.73 1.526 0.75 0.89 0.79 0.84 3.22 10.00 cfs 4700.22 1.76 1.547 0.76 0.89 0.80 0.87 3.30 Culvert Data: Path Culvert 3+32 Headwater Elevation (ft) Total Discharge (cfs) Culvert 1 Discharge (cfs) Roadway Discharge (cfs) Iterations 4695.42 0.50 0.50 0.00 1 4695.75 1.45 1.45 0.00 1 4696.01 2.40 2.40 0.00 1 4696.40 3.68 3.68 0.00 1 4696.61 4.30 4.20 0.07 22 4696.67 5.25 4.33 0.91 6 4696.71 6.20 4.41 1.76 4 4696.74 7.15 4.48 2.66 4 4696.77 8.10 4.54 3.53 3 4696.79 9.05 4.60 4.43 3 4696.82 10.00 4.65 5.34 3 4696.60 4.17 4.17 0.00 Overtopping Total Discharge (cfs) Headwater Elevation (ft) Inlet Control Depth (ft) Outlet Control Depth (ft) Normal Depth (ft) Critical Depth (ft) Outlet Depth (ft) Tailwater Depth (ft) Tailwater Velocity (ft/s) 0.50 cfs 4695.42 0.39 0.0* 0.21 0.29 0.21 0.30 1.38 1.45 cfs 4695.75 0.72 0.268 0.36 0.51 0.38 0.45 1.80 2.40 cfs 4696.01 0.98 0.576 0.47 0.66 0.51 0.54 2.04 3.68 cfs 4696.40 1.37 1.149 0.62 0.82 0.66 0.64 2.28 4.30 cfs 4696.61 1.58 1.344 0.68 0.86 0.72 0.67 2.37 5.25 cfs 4696.67 1.64 1.395 0.69 0.87 0.73 0.73 2.49 6.20 cfs 4696.71 1.68 1.428 0.70 0.88 0.74 0.77 2.59 7.15 cfs 4696.74 1.71 1.458 0.71 0.89 0.75 0.82 2.69 8.10 cfs 4696.77 1.74 1.483 0.72 0.89 0.76 0.85 2.77 9.05 cfs 4696.79 1.76 1.506 0.72 0.89 0.77 0.89 2.85 10.00 cfs 4696.82 1.79 1.505 0.73 0.90 0.77 0.93 2.92 * Full Flow Headwater elevation is below inlet invert. Culvert Data: Culvert 9+34 Headwater Elevation (ft) Total Discharge (cfs) Culvert 1 Discharge (cfs) Roadway Discharge (cfs) Iterations 4691.38 0.50 0.50 0.00 1 4691.65 1.45 1.45 0.00 1 4691.85 2.40 2.40 0.00 1 4692.02 3.35 3.35 0.00 1 4692.18 4.30 4.30 0.00 1 4692.33 5.25 5.25 0.00 1 4692.47 6.20 6.20 0.00 1 4692.62 7.15 7.15 0.00 1 4692.77 8.10 8.10 0.00 1 4692.88 8.81 8.81 0.00 1 4692.96 10.00 9.25 0.73 7 4692.90 8.92 8.92 0.00 Overtopping Total Discharge (cfs) Headwater Elevation (ft) Inlet Control Depth (ft) Outlet Control Depth (ft) Normal Depth (ft) Critical Depth (ft) Outlet Depth (ft) Tailwater Depth (ft) Tailwater Velocity (ft/s) 0.50 cfs 4691.38 0.35 0.380 0.28 0.26 0.40 0.40 0.79 1.45 cfs 4691.65 0.62 0.654 0.49 0.45 0.59 0.59 1.03 2.40 cfs 4691.85 0.81 0.854 0.64 0.59 0.72 0.72 1.16 3.35 cfs 4692.02 0.99 1.025 0.77 0.70 0.81 0.81 1.26 4.30 cfs 4692.18 1.14 1.182 0.90 0.79 0.89 0.89 1.35 5.25 cfs 4692.33 1.28 1.330 1.04 0.88 0.96 0.96 1.41 6.20 cfs 4692.47 1.41 1.475 1.20 0.96 1.03 1.03 1.47 7.15 cfs 4692.62 1.55 1.619 1.50 1.04 1.08 1.08 1.53 8.10 cfs 4692.77 1.70 1.767 1.50 1.10 1.13 1.13 1.58 8.81 cfs 4692.88 1.82 1.882 1.50 1.15 1.17 1.17 1.61 10.00 cfs 4692.96 1.90 1.959 1.50 1.18 1.23 1.23 1.66 Culvert Data: Culvert 9+71 Headwater Elevation (ft) Total Discharge (cfs) Culvert 1 Discharge (cfs) Roadway Discharge (cfs) Iterations 4692.25 0.50 0.50 0.00 1 4692.29 1.65 1.65 0.00 1 4692.36 2.80 2.80 0.00 1 4692.43 3.95 3.95 0.00 1 4692.50 5.10 5.10 0.00 1 4692.62 6.25 6.25 0.00 1 4692.77 7.40 7.40 0.00 1 4692.99 8.81 8.81 0.00 1 4693.15 9.70 9.70 0.00 1 4693.35 10.85 10.72 0.09 16 4693.40 12.00 10.99 0.98 6 4693.33 10.64 10.64 0.00 Overtopping Total Discharge (cfs) Headwater Elevation (ft) Inlet Control Depth (ft) Outlet Control Depth (ft) Normal Depth (ft) Critical Depth (ft) Outlet Depth (ft) Tailwater Depth (ft) Tailwater Velocity (ft/s) 0.50 cfs 4692.25 0.36 1.422 0.29 0.26 1.50 1.50 0.00 1.65 cfs 4692.29 0.66 1.456 0.53 0.48 1.50 1.50 0.00 2.80 cfs 4692.36 0.91 1.530 0.71 0.64 1.50 1.50 0.00 3.95 cfs 4692.43 1.12 1.595 0.87 0.76 1.50 1.50 0.00 5.10 cfs 4692.50 1.32 1.668 1.04 0.87 1.50 1.50 0.00 6.25 cfs 4692.62 1.51 1.792 1.24 0.97 1.50 1.50 0.00 7.40 cfs 4692.77 1.71 1.942 1.50 1.05 1.50 1.50 0.00 8.81 cfs 4692.99 1.99 2.160 1.50 1.15 1.50 1.50 0.00 9.70 cfs 4693.15 2.20 2.317 1.50 1.20 1.50 1.50 0.00 10.85 cfs 4693.35 2.45 2.515 1.50 1.26 1.50 1.50 0.00 12.00 cfs 4693.40 2.53 2.571 1.50 1.27 1.50 1.50 0.00 V:17055_Storm_Drainage_Plan.docx 13 (2/1/22) SH/rrr/ed Appendix D WATER QUANTITY AND QUALITY CALCULATIONS Project: Glen Lake Rotary Park Project #: 17055 Date: 10/14/2021 Design Storm Frequency = 10 years Discharge Rate, d = 0.46 cfs - Phase 1 Peak Pre-Development Runoff Flow Rate Time of Concentration = 5.00 minutes 21323.53 0.490 0.95 1 0.95 37190.18 0.854 0.3 1 0.30 2815.56 0.065 0.8 1 0.80 61329.28 1.41 0.549 1 0.549 Rainfall Rainfall Peak Flow Duration, t Intensity, i = Cwd x A x i (min) (in/hr)(ft3/s) 1 9.16 7.08 5 3.22 2.49 10 2.05 1.59 11 1.93 1.49 12 1.82 1.41 13 1.73 1.34 14 1.65 1.27 15 1.58 1.22 20 1.31 1.01 25 1.13 0.87 30 1.00 0.78 35 0.91 0.70 40 0.83 0.64 45 0.77 0.60 50 0.72 0.56 55 0.68 0.52 60 0.64 0.49 75 0.55 0.43 90 0.49 0.38 105 0.44 0.34 120 0.41 0.32 150 0.35 0.27 180 0.31 0.24 360 0.20 0.15 720 0.13 0.10 1440 0.08 0.06 Impervious Landscape Gravel Totals Runoff Volume Discharge Volume RATIONAL METHOD FOR WATER QUANTITY VOLUME CALCULATIONS PHASE 1 EXISTING ANALYSIS Surface Type Area A (ft2) Area (acres) Runoff Coefficient C Frequency Factor Cf C x Cf 424.86 27.60 397.26 746.25 138.00 608.25 Site Detention = Cwd x A x i x t = d x t = Runoff Volume - Discharge Volume (ft3) (ft 3) (ft 3) 1212.29 552.00 660.29 1310.76 690.00 620.76 951.14 276.00 675.14 1096.17 414.00 682.17 1013.81 331.20 682.61 1042.62 358.80 683.82 1070.01 386.40 683.61 983.40 303.60 679.80 1545.13 1104.00 441.13 1610.16 1242.00 368.16 1397.13 828.00 569.13 1474.58 966.00 508.58 1656.00 124.73 1925.38 2070.00 ----- 1670.64 1380.00 290.64 1727.31 1518.00 209.31 1780.73 5415.91 39744.00 ----- 2615.71 4968.00 ----- 3333.88 9936.00 ----- 4249.23 19872.00 ----- 2269.64 3312.00 ----- 2454.01 4140.00 ----- 2052.24 2484.00 ----- 2166.01 2898.00 ----- Project: Glen Lake Rotary Park Project #: 17055 Date: 10/14/2021 Design Storm Frequency = 10 years Discharge Rate, d = 0.81 cfs - Phase 1 Peak Pre-Development Runoff Flow Rate Time of Concentration = 5.00 minutes 40202.75 0.923 0.95 1 0.95 61259.92 1.406 0.3 1 0.30 5942.05 0.136 0.8 1 0.80 107404.72 2.47 0.571 1 0.571 Rainfall Rainfall Peak Flow Duration, t Intensity, i = Cwd x A x i (min) (in/hr)(ft3/s) 1 9.16 12.90 5 3.22 4.53 10 2.05 2.89 11 1.93 2.71 12 1.82 2.56 13 1.73 2.43 14 1.65 2.32 15 1.58 2.22 20 1.31 1.84 25 1.13 1.59 30 1.00 1.41 35 0.91 1.28 40 0.83 1.17 45 0.77 1.09 50 0.72 1.01 55 0.68 0.95 60 0.64 0.90 75 0.55 0.78 90 0.49 0.69 105 0.44 0.63 120 0.41 0.57 150 0.35 0.50 180 0.31 0.44 360 0.20 0.28 720 0.13 0.18 1440 0.08 0.11 Impervious Landscape Gravel Totals Runoff Volume Discharge Volume RATIONAL METHOD FOR WATER QUANTITY VOLUME CALCULATIONS PHASE 1 & 2 EXISTING ANALYSIS Surface Type Area A (ft2) Area (acres) Runoff Coefficient C Frequency Factor Cf C x Cf 773.88 48.47 725.41 1359.29 242.37 1116.92 Site Detention = Cwd x A x i x t = d x t = Runoff Volume - Discharge Volume (ft3) (ft 3) (ft 3) 2208.18 969.49 1238.69 2387.55 1211.86 1175.69 1732.50 484.74 1247.76 1996.67 727.12 1269.55 1791.27 1846.66 1899.13 1949.03 533.22 581.69 630.17 678.64 1258.05 1264.97 1268.96 1270.39 2814.46 1938.98 875.48 2932.91 2181.35 751.56 2544.87 1454.23 1090.64 2685.95 1696.61 989.34 2908.47 335.13 3507.08 3635.58 ----- 3043.08 2423.72 619.36 3146.30 2666.09 480.21 3243.60 9865.08 69803.18 ----- 4764.52 8725.40 ----- 6072.67 17450.80 ----- 7739.99 34901.59 ----- 4134.16 5816.93 ----- 4469.98 7271.16 ----- 3738.17 4362.70 ----- 3945.39 5089.82 ----- Project: Glen Lake Rotary Park Project #: 17055 Date: 10/14/2021 Design Storm Frequency = 10 years Discharge Rate, d = 0.93 cfs - Phase 1 Peak Pre-Development Runoff Flow Rate Time of Concentration = 5.00 minutes 85711.71 1.968 0.95 1 0.95 99673.25 2.288 0.3 1 0.30 8899.58 0.204 0.8 1 0.80 194284.53 4.46 0.610 1 0.610 Rainfall Rainfall Peak Flow Duration, t Intensity, i = Cwd x A x i (min) (in/hr)(ft3/s) 1 9.16 24.91 5 3.22 8.75 10 2.05 5.58 15 1.58 4.29 20 1.31 3.55 25 1.13 3.07 26 1.10 3.00 27 1.08 2.92 28 1.05 2.86 29 1.03 2.79 30 1.00 2.73 31 0.98 2.67 32 0.96 2.62 33 0.94 2.57 34 0.93 2.52 35 0.91 2.47 40 0.83 2.27 45 0.77 2.10 50 0.72 1.96 55 0.68 1.84 60 0.64 1.74 75 0.55 1.51 90 0.49 1.34 105 0.44 1.21 120 0.41 1.11 150 0.35 0.96 180 0.31 0.85 360 0.20 0.54 720 0.13 0.35 1440 0.08 0.22 4972.16 5027.72 5082.16 5135.54 1734.66 1790.61 1846.57 1902.53 3237.50 3237.10 3235.59 3233.01 RATIONAL METHOD FOR WATER QUANTITY VOLUME CALCULATIONS PHASE 1, 2 & 3 (MASTER) EXISTING ANALYSIS Surface Type Area A (ft2) Area (acres) Runoff Coefficient C Frequency Factor Cf C x Cf Site Detention = Cwd x A x i x t = d x t = Runoff Volume - Discharge Volume (ft3) (ft 3) (ft 3) Impervious Landscape Gravel Totals Runoff Volume Discharge Volume 3346.33 559.57 2786.76 2625.48 279.78 2345.69 1494.75 55.96 1438.79 4857.44 1622.74 3234.70 4915.42 1678.70 3236.72 3856.56 839.35 3017.21 4265.10 1119.13 3145.96 3220.42 3226.63 3231.36 4611.56 4675.30 4737.46 4798.15 1398.92 1454.87 1510.83 1566.79 3212.64 5664.91 2518.05 3146.86 5877.71 2797.84 3079.87 5187.91 1958.48 3229.42 5436.13 2238.27 3197.86 6773.92 4196.75 2577.17 7220.27 5036.10 2184.17 6077.09 3077.62 2999.47 6265.01 3357.40 2907.60 8633.77 8393.51 240.26 9202.67 10072.21 ----- 7620.52 5875.45 1745.07 7985.13 6714.80 1270.32 19054.40 80577.66 ----- 11729.36 20144.41 ----- 14949.78 40288.83 ----- Project: Glen Lake Rotary Park Project #: 17055 Date: 02/01/2022 Time of Concentration= 5 mins Precipitaton Depth= 0.5 in Vi,e,c= 0 acre-feet Mannings roughness (n)= 0.22 Design Flow Depth (y)= 3 inches Residence Time (t)= 9 minutes POST DEVELOPMENT BASINS WS Area (sf)% IC Rv RRV (acre-ft) RTV (acre-ft) Q (in)CN Ia Ia/P C0 C1 C2 qu Unit Peak Discharge (cfs/mi2/ in) RTF (cfs) Long. Slope (ft/ft) Bottom Width (ft) Min. Side Slope (z:1) A (ft2) V (ft/sec) L (ft) Provided Ditch Length (ft) 1 14,880 59% 0.58 0.008 0.008 0.29 97.55 0.0502 0.100 2.305 -0.514 -0.117 529.024 0.082 0.005 0.72 4.00 0.75 0.11 2 16,167 47% 0.47 0.007 0.007 0.24 96.63 0.0698 0.140 2.278 -0.510 -0.106 506.307 0.070 0.005 0.47 4.00 0.75 0.09 3 10,462 84% 0.81 0.008 0.008 0.40 99.09 0.0183 0.100 2.306 -0.514 -0.118 529.259 0.080 0.005 0.69 4.00 0.75 0.11 58 59 4 7,259 4% 0.09 0.001 0.001 0.04 89.09 0.2449 0.490 1.696 -0.087 0.001 61.792 0.001 0.005 -0.99 4.00 0.75 0.00 1 N/A 5 8,499 60% 0.59 0.005 0.005 0.29 97.63 0.0486 0.100 2.306 -0.514 -0.118 529.259 0.047 0.005 0.00 4.00 0.75 0.06 34 50 6 15,741 46% 0.46 0.007 0.007 0.23 96.49 0.0728 0.146 2.274 -0.510 -0.105 502.983 0.066 0.006 0.51 3.00 0.69 0.10 51 107 7 11,472 68% 0.66 0.007 0.007 0.33 98.16 0.0374 0.100 2.306 -0.514 -0.118 529.259 0.072 0.006 0.63 3.00 0.69 0.10 56 109 8 25,048 38% 0.40 0.009 0.009 0.20 95.76 0.0886 0.177 2.251 -0.506 -0.096 485.528 0.086 0.004 1.53 2.00 0.63 0.14 75 213 9 21,028 44% 0.45 0.009 0.009 0.22 96.32 0.0764 0.153 2.269 -0.509 -0.103 498.987 0.084 0.006 1.11 2.00 0.63 0.13 72 144 10 31,461 41% 0.42 0.013 0.013 0.21 96.04 0.0824 0.165 2.260 -0.508 -0.099 492.266 0.117 0.015 0.92 2.00 0.63 0.19 101 223 11 29,868 28% 0.30 0.009 0.009 0.15 94.46 0.1172 0.234 2.199 -0.491 -0.073 439.729 0.071 0.008 0.69 2.00 0.63 0.11 62 138 RUNOFF TREATMENT FLOW RATE CALCULATIONS Permanent Detention Pond [RRV] Runoff Reduction Volume P=0.5 inches Rv=0.332 I=31%Impervious A=0.685678 acres RRV= 0.009482 acre-feet 413.0 ft3 [RTV] Runoff Treatment Volume Vi,e,c =0 acre-feet RTV = 0.009482 acre-feet 413.0 ft3 [RTF] Runoff Treatment Flow Rate Curve Number Determination (CN) P =0.5 inches Q =0.165949 inches CN =94.9 a Biofiltration Swale Example Calculation See Runoff Treatment Flow Rate and Biofiltration Swale Table for Results for Each Watershed Tc =5 minutes Ia =0.11 Ia/P =0.21 Coefficents for Type I distribution I/P C0 C1 C2 0.1 2.3055 -0.51429 -0.1175 0.2 2.23537 -0.50387 -0.08929 0.25 2.18219 -0.48488 -0.06589 0.3 2.10624 -0.45695 -0.02835 0.35 2.00303 -0.40769 0.01983 0.4 1.87733 -0.32274 0.05754 0.45 1.76312 -0.15644 0.00453 0.5 1.67889 -0.0693 0 C0 =2.219821 C1 =-0.49832 C2 =-0.08245 qu=458.7483 Unit Peak Discharge RTF =0.08 cfs Bio Swale Geometry Flow Resistance Coefficient in Biofiltration Swales (Table 5.6-1) 0.22 Design Flow Depth (in) 3 Grass-legume mix on lightly compacted topsoil w/ 3-inch medium compost blanket Dryland Grasses s =0.0175 ft/ft - recommended range 1.5-5% n =0.22 z =4 y =0.25 feet b =-0.08 feet or 2 feet if calculated is less than 2 feet A =0.75 ft2 V =0.11 ft/sec must be less than 1 ft/sec t =9 minutes L =58.72 feet Flow Depth:3 inches Channel Slope:1.75% Bottom Width:2.00 feet Side Slope:4 :1 Length:58.72 feet Swale Geometry V:17055_Storm_Drainage_Plan.docx 14 (2/1/22) SH/rrr/ed Appendix E GROUNDWATER ELEVATION EXHIBIT !. > >> > > > > > # # #* #* #*East Gallatin River4688469746894690469246914693469546944696EGRAIrrigationWell VW-1 VW-2 VW-5 VW-4 VW-3 1 2 - old 2 7 8 10 MW-1 MW-2MW-5 MW-4 MW-6 3 4 5 6 9 11 12 . Legend Active Monitoring WellProposed Monitoring Well >Historic monitoring well #*Proposed soil vapor probe #Historic soil vapor probe !.EGRA Irrigation Well Inferred_Landfill_Boundary Potentiometric Contours East Gallatin Recreation Area 0 100 200 300 40050 1 inch = 100 feet Job#: COBM02 Date: 2/26/2021 FIGURE 2 Monitoring Locations Old Bozeman City Landfill Path: M:\COBM03\Figure 2 - Monitoring Locations.mxd, Author: svandaele Location of theBozeman Old City Landfill Glen Lake Bridger Creek Golf Course Facilities Building ? ?? Bridger Vale Subdivision Approximate Extent of Buried Landfill Materials Unknown ? V:17055_Storm_Drainage_Plan.docx 15 (2/1/22) SH/rrr/ed Appendix F MAINTENANCE PLAN February 1, 2021 Project No. 17055 STORM DRAINAGE FACILITY MAINTENANCE PLAN FOR GLEN LAKE ROTARY PARK BOZEMAN, MONTANA OVERVIEW NARRATIVE The purpose of this maintenance plan is to outline the necessary details related to ownership, responsibility and cleaning schedule for the storm drainage facilities for Glen Lake Rotary Park. This plan has been completed in accordance with The City of Bozeman Design Standards and Specifications Policy, dated March 2004. The site stormwater improvements have been designed with the intent to meet the current City of Bozeman drainage regulations for the entire site to the extent feasible. Specific site information and criteria are described below: I. Ownership of Facilities Glen Lake Rotary Park The City of Bozeman will own all stormwater facilities which includes the drainage swales, piping, structures, and detention basins within the site boundary. II. Inspection Thresholds for Cleaning Drainage Swale Remove trash, debris, yard waste, accumulated sediment, and maintain grass heights as specified during the design documents, remove all clippings. Evidence of rodent holes or water seepage through embankments. Surface Pond Remove vegetation and debris at pipe inlets/outlets to pond. Fix erosion and scouring. If piping or erosion is visible, consult engineer. Outlet Structure The structure is not damaged, clogged, or defective. If sediment sump exceeds 5 inches or grate is more than 25% clogged with debris. Remove vegetation and debris from orifice. V:Maintenance.docx 2 (2/1/22) SH/rrr/ed III. Cleaning Drainage Swale Remove and dispose of debris clogging the area. Reseed as needed during fall seeding to maintain 90% turf grass cover and inspect side slopes for evidence of erosion. Surface Pond Remove vegetation and debris from pond inlets and outlets. Check for slumping or sloughing of pond slopes. Outlet Structures Clean grate and orifice of structure by remove and dispose of debris. Use catch basin vacuum to remove sediment and debris. IV. Schedule Drainage Swale Inspection: Every 3 months and after storms Surface Pond Inspection: Every 6 months and after storm events Outfall Structures Inspection: Every 6 months and after storm events Vacuum: Every 5 years or as needed based on inspection V. Responsible Party Glen Lake Rotary Park The City of Bozeman will be responsible for the inspection and maintenance of all stormwater facilities located within the project limits I agree to the above operation, maintenance and replacement schedule detailed above. Signature: ________________________________________ __ Glan Lake Rotary Park Representative