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HomeMy WebLinkAboutSW1221003_O&M Agreement/Plan_20221031Operation & Maintenance Agreement Project Name: Project Location: Mills River Townhomes Single -Family Attached Development 2211, 2253 & 2035 Jeffress Road, Mills River NC 28759 Cover Page Maintenance records shall be kept on the following SCM(s). This maintenance record shall be kept in a log in a known set location. Any deficient SCM elements noted in the inspection will be corrected, repaired, or replaced immediately. These deficiencies can affect the integrity of structures, safety of the public, and the pollutant removal efficiency of the SCM(s). The SCM(s) on this project include (check all that apply & coi Infiltration Basin Quantity: Infiltration Trench Quantity: Bioretention Cell Quantity: Wet Pond Quantity: Stormwater Wetland Quantity: Permeable Pavement Quantity: Sand Filter Quantity: Rainwater Harvesting Quantity: Green Roof Quantity: Level Spreader - Filter Strip Quantity: Proprietary System Quantity: Treatment Swale Quantity: Dry Pond Quantity: Disconnected Impervious Surface Present: User Defined SCM Present: Low Density Present: onding O&M sheets will Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): Location(s): /4' Location(s): Location(s): Location(s): No Location(s): Yes Location(s): No Type: De aaaea automaucai 135.39 / -82.57 1 acknowledge and agree by my signature below that I am responsible for the performance of the maintenance procedures listed for each SCM above, and attached O&M tables. I agree to notify NCDEQ of any problems with the system or prior to any changes to the system or responsible party. Signature: Responsible Party: Title & Organization: Street address: City, state, zip: Phone number(s): Email: David Benjamin Graves Manager & Mills River TH, LLC 1855 E. Main Street, Ste 14-7 Spartanburg, SC 29307 843-615-7604 rjordan@longbranchdevelopment.com Date: i a Notary Public for the State of Spti�t Ct� rod; Gam. County of V1-r,� S6,L4 do hereby certify that �D�iV —� ��.trr+:,� C-ZY"t S personally appeared before me this S day of C)C.1 �72✓ 2�D^2--2-- and acknowledge the due execution of the Operations and Maintenance Agreement . Witness riVjhorm6ppd official seal, _, ` l L Uv � • Seal My commission expires 10 / t-7 l 2b -2� STORM-EZ 10/512022 Version 1.5 O&M Agreement Page 1 of 1 IIIV 2 � Ab TABLE OF CONTENTS INTRODUCTION ............................... 2 BAYFILTER...................................3 BASIC PRINCIPLES OF FILTRATION ............... 4 BAYFILTER PRODUCTS ......................... 6 BAYFILTER OPERATION ........................ 8 SYSTEM DESIGN & SIZING ..................... 10 INSTALLATION...............................15 INSPECTION & MAINTENANCE .................. 17 AVAILABILITY & COST ......................... 18 BAYFILTER SPECIFICATIONS ................... 18 INTRODUCTION Clean water is essential to quality of life. BaySaver Technologies is 100% committed to minimizing pollution in stormwater which helps protect our water resources. By collaborating with the regulatory and engineering community to develop products and processes, BaySaver continually develops state of the art stormwater filters that are proven to effectively remove pollutants such as sediments, phosphorous, metals, nitrogen, trash, and hydrocarbons. BAYFILTER The BayFilter cartridge system is an ongoing commitment to state of the art stormwater treatment. The compound spiral media configuration allows for a large filter surface area in a compact footprint. This configuration results in the most efficient and effective stormwater filter available in the marketplace. The BayFilter is available in multiple sizes with multiple media configurations to meet any flow rate and design consideration while being able to target specific pollutants. A BayFilter System is typically a concrete structure (precast vault, manhole, or cast in place structure) with a single or multiple BayFilter cartridges. Inside the structure the BayFilters are connected to an outlet manifold through which the treated water exits the system. POLYMER SEAL INLET DRAI NAG E MATERIAL MEDIA SPIRAL OUTLET DRAINAGE MATERIAL BayFilter Cutaway Plan View OUTLET PIPE AIR RELEASE VALVE OUTLET PATHWAY FLOW CONTROL ORIFICE INLET PLATE FI LTER LEG Profile View LLLL�Y� 9to BASIC PRINCIPLES OF STORMWATER FILTRATION Stormwater treatment has unique requirements, which often require the treatment of large volumes of water at relatively high flow rates to high levels of pollutant removal with long periods of time between maintenance intervals. At BaySaver we believe it is our responsibility to engineer a balance within these variables to provide effective stormwater treatment at an exceptional value to our clients. What makes for an effective and efficient stormwater filter? A filter must be able to remove the pollutants of concern and function for a reasonable period of time as defined by industry and regulatory standards. A filter system should also be designed to limit re -suspension or release of pollutants that have been collected between maintenance periods. The traditional pollutants of concern in stormwater is sediment. Phosphorous, metals, turbidity, nitrogen, fecal coliform, and bacteria are also pollutants of concern although they are not commonly regulated nationwide. BaySaver Technologies has completed both field and laboratory testing of the BayFilter. Testing demonstrates BayFilter's effectiveness and efficiency at capturing the pollutants listed above. Settling and filtration are the two primary methods to remove pollutants from stormwater. Some settling of particles and pollutants occurs as the influent enters the filter vault. Settling typically removes the larger particles and debris, it does not remove the small particles or any dissolved materials. It is the filter which performs the work of removing the very small particles, and dissolved nutrients and metals. The media within a filter must be small enough to intercept the tiny sediment particles which won't settle (fig. 1), and be capable of attracting and attaching charged and elemental particles through ion exchange. The area of media provided by a stormwater filter is an important factor to consider when selecting and specifying a filter system. The more surface area provided by the media, the greater the potential flow through and across the media and the greater the pollutant removal potential of the filter. The vertically oriented and patented compound spiral media Figure 1: Coarse Industry Media Figure 2: BayFilter Media configuration of the BayFilter maximizes a media filter's area potential. The particle size of the media is also important with respect to pollutant interception and adsorption. A tightly packed, fine media (fig 2) captures a greater percentage of fine and dissolved pollutants when compared to a loosely packed, coarse media or a membrane media. A fine and tightly packed media not only minimizes the interstitial spaces between the media particles to optimize interception of pollutants, it also maximizes the amount of surface area in a given volume provided by the media for ion exchange. The quantity of sediment a filter is capable of capturing is a significant component to filter longevity. A filter must be able to treat large quantities of sediment while maintaining claimed flow rates and removal efficiencies. The sediment loading capacity of the BayFilter is 350 pounds (158.7 kg) for the 45 gpm (170.3 Ipm) and 30 gpm (113.6 Ipm) cartridges. Surface area and loading rate contribute significantly to filter longevity. Greater filter surface area (sf) allows for a reduced loading rate (gpm/sf of filter media), which in turn increases the service life of the filter. For example, a 10 square foot (0.9 m2) filter with a loading rate of 1 GPM (3.8 I/min) per square foot of filter area will pass 10 GPM (37.9 I/min). A 20 ft2 filter with a loading rate of 0.5 GPM (1.9 I/min) per square foot of filter area will also pass 10 GPM (37.9 I/min). If one gallon of treated water will occlude one square foot of filter area every 10 days, a 10 ft2 (0.9 m2) filter flowing at one GPM (3.8 I/min) will be expired in 100 days. A 20 ft2 (1.9 m2) filter flowing at 0.5 GPM (1.9 I/min) will be expired in 400 days. Increasing media area and reducing flow rate has a beneficial impact on pollutant removal and filter longevity and these are some of the core engineering principles on which the BayFilter design is based. BaySaver Technologies is committed to the purpose of protecting public waterways. Permanently capturing pollutants, effectively backwashing media, allowing media to drain between storm events, and providing an economically reasonable maintenance interval are key design parameters for properly functioning stormwater filtration systems. The BayFilter cartridge system helps meet and exceed these key requirements needed to protect our water resources. , 0"t,16 7WO21 Top of Cartridge Bottom of Cartridge BAYFILTER PRODUCT DETAILS BayFilter 545 Size = 28" (711 mm) diameter Weight = 250 lbs. (113 kg) Media Area = 90 ft2 (8.4 m2) Flow Rate = 45 gpm (170 I/min) Flow Rate per Square Foot = 0.50 gpm/ft2 (20 I/min/m2) Minimum Operational Head = 32" (813 mm) Recommended Design Head = 34" (864 mm) Sediment Capture Capacity = 350 Ibs (159 kg) Manifold Diameter = 6" (152 mm) BayFilter 530* Size = 28" (711 mm) diameter Weight = 250 Ibs. (113 kg) Media Area = 90 ft2 (8.4 m2) Flow Rate = 30 gpm (114 I/min) Flow Rate per Square Foot = 0.33 gpm/ft2 (13 I/min/m2) Minimum Operational Head = 30" (762 mm) Recommended Design Head = 32" (813 mm) Sediment Capture Capacity = 350 Ibs (159 kg) Manifold Diameter = 4" (102 mm) BayFilter 522** Size = 28" (711 mm) diameter Weight = 125 Ibs. (57 kg) Media Area = 45 ft2 (4.2 m2) Flow Rate = 22.5 gpm (85 I/min) Flow Rate per Square Foot = 0.50 gpm/ft2 (20 I/min/m2) Minimum Operational Head =18" (457 mm) Recommended Design Head = 20" (508 mm) Sediment Capture Capacity = 175 Ibs (79 kg) Manifold Diameter = 3" (76 mm) 6' O 36' 32' 6' B.AYFILTER 545 028' I BayFilter 545 d 4' 34' 30' x BArFILTER 530 028' BayFilter 530 1' Q x 22• 18' TBAYFILTER 522 mze• BayFilter 522 NOTES: The 500 series is for Total Suspended Solids (TSS) and Phosphorous and utilizes EMC media. *BayFilter 530 replaces BFC cartridge. ** BayFilter 522 replaces 545L cartridge. BayFilter 645 Size = 28" (711 mm) diameter Weight = 250 lbs. (113 kg) Media Area = 90 ft2 (8.4 m2) Flow Rate = 45 gpm (170 I/min) Flow Rate per Square Foot = 0.50 gpm/ft2 (20 I/min/m2) Minimum Operational Head = 32" (813 mm) Recommended Design Head = 34" (864 mm) Sediment Capture Capacity = 350 Ibs (159 kg) Manifold Diameter = 6" (152 mm) BayFilter 630 Size = 28" (711 mm) diameter Weight = 250 Ibs. (113 kg) Media Area = 90 ft2 (8.4 m2) Flow Rate = 30 gpm (114 I/min) Flow Rate per Square Foot = 0.33 gpm/ft2 (13 I/min/m2) Minimum Operational Head = 30" (762 mm) Recommended Design Head = 32" (813 mm) Sediment Capture Capacity = 350 Ibs (159 kg) Manifold Diameter = 4" (102 mm) BayFilter 622 Size = 28" (711 mm) diameter Weight =125 Ibs. (57 kg) Media Area = 45 ft2 (4.2 m2) Flow Rate = 22.5 gpm (85 I/min) Flow Rate per Square Foot = 0.50 gpm/ft2 (20 I/min/m2) Minimum Operational Head = 18" (457 mm) Recommended Design Head = 20" (508 mm) Sediment Capture Capacity = 175 Ibs (79 kg) Manifold Diameter = 3" (76 mm) k -�nr, � ( 6' BAYFILTER 645 28 BayFilter 645 Q 4- 3d' 22.5' x 30' 4' x 8AYFILTER 630 028, BayFilter 630 3" O BAYF•LTER 622 BayFilter 622 NOTES: The 600 series is for enhanced metals treatment. BAYFILTER OPERATION Stormwater runoff enters the manhole or concrete structure via an inlet pipe and begins to fill the structure. When the water surface elevation in the vault/manhole reaches the minimum operating level, water flows through the BayFilter driven by a hydrostatic head. Within the BayFilter, the water flows through a proprietary filter media and drains via a vertical pipe. The vertical pipe is connected to the under drain system, which conveys filtered water to the outfall. During atypical storm event, the BayFilter system has four cycles: A. BayFilter cartridge fills and releases air B. Positive head filtration C. Siphon (negative head) filtration D. Siphon break and hydrodynamic backwash The cycle operation of a BayFilter is as follows: A. BayFilter cartridge fill and air release: The BayFilter vault and BayFilter cartridges fill when stormwater flow enters the system. As the vault fills, water enters the BayFilter cartridge through the inlet plate on the bottom. Air is purged from the media spiral and filter housing during this process. The air release is critical for the proper functioning of the siphon. The siphon draws flow through the BayFilter during periods of low water in the vault. BayFilter Vault OUTLET PIPE AIR RELEASE VALVE � l.J POLYMER SEAL--- • -- OUTLET I _ PATHWAY INLET DRAINACE MATERIAL : MEDIA FLAW • CONTROL SPIRAL;;, M1 ORIFICE: OUTLET DRAINAGE MATERIAL.• I. INLET PLATE FILTER LEG .01 BayFilter Cutaway Cartridge Filling _VE B. Positive Head Filtration: Water enters the Filter from the bottom of the filter housing and travels upward through the inlet -flow conduit -spiral. From the inlet spiral, untreated water flows horizontally through the engineered media. Treated water exits the engineered media and flows into the outlet -flow conduit -spiral. Treated water flows vertically to the top of the cartridge where it can exit through the outlet pipe —please see product details (pg.6) for operating head levels. Finally, filtered water leaves the system via the outlet. C. Siphon (Negative Head) Filtration: After the water level in the vault falls below the top of the filter cartridge - minimum operating head level, a siphon is established and water will continue to flow through the filter media until the siphon is broken. During siphon, the water level in the vault will decrease until it reaches the inlet plate of the BayFilter. D. Siphon Break and Hydrodynamic Backwash: When the water level drops below the inlet plate, air enters the filter and the siphon breaks. Once the siphon breaks, a gravity -driven backwash occurs with all of the water flowing from the outlet pathway backwards through the filter media. This backwash has the effect of dislodging particles captured in the filtration layers and re-establishing porosity. Dislodged particles are transported back in to the filter vault and accumulate on the filter vault floor. Each BayFilter has a maximum flow rating. At this flow, each cartridge can treat the specified total sediment load before requiring maintenance. BayFilter flow may also be custom regulated to meet specified design parameters by modifying the flow control orifice. Please contact BaySaver for custom design requirements. Positive Filtration Siphon Filtration Siphon Break Backwash BAYFILTER SYSTEM DESIGN &SIZING The BayFilter cartridge system design is easily completed in four phases: A. BayFilter System Configuration B. BayFilter Site Plan Placement C. BayFilter System Sizing D. Final Check The design process can be iterative until the determined design parameters are satisfied. Some of the items to consider when designing a stormwater filtration system: • Site specific constraints and proposed BayFilter system location • BayFilter system configuration —on-line or off-line • Pretreatment requirements • Operating head • Treatment efficiency requirements and local regulations • Pollutant loading (sediment load) • Treatment flow rates and hydraulics • Maintenance intervals BAYFILTER SYSTEM CONFIGURATION BayFilter systems can accommodate any treatment flow requirement. The peak design flow through the storm drain system will be significantly greater than the treatment design flow through BayFilter. It is a best practice to only convey the required treatment flow through a stormwater filter and this will extend the filter's life cycle. Conveying the peak design flow around a stormwater filter is considered off-line treatment. Off -Line Design Schematics of off-line BayFilter systems are shown below. In Figure 1, the bypass structure diverts treatment flows to the BayFilter system and allows high flows to pass to a separate outfall. The bypass structure will feature flow controls designed by an engineer to ensure that the required treatment flows are sent to the BayFilter. In Figure 2, this same concept is accomplished within a 3-chamber vault. In stormwater filter system installations, sediment will accumulate in the filter cartridge and on the vault floor. In off-line installations, high intensity flows are routed away from the vault minimizing the risk of re- suspending the sediment accumulated on the vault floor. In online applications it is possible for high flows to mobilize and release this sediment. OVERFLOW PIPE FLOW- `JUNCTION SPUTTER MANHOLE INLET PIPE OUTLET PIPE 6AYFI LTER Figure 1: Offline Configuration External Bypass w � i�llill�'itil� �7 Figure 2: Inline Configuration Internal Bypass Operating Head Head is required to activate BayFilter flow and establish siphon flow. The height of individual BayFilter cartridges will determine the operating head. Please consult product details for individual operating head levels. The drainage system and network does not need to provide the operating head. Filter systems can easily be designed on sites where the elevation drop of the hydraulic grade line is less than the required operating head of the filter. Consult BaySaver Technologies Engineering Department for verification based on your particular site conditions. Pretreatment Regional regulations may require pretreatment of stormwater flows prior to flow entering filters. Pretreatment will remove a portion of the influent pollutant load. This will lessen the pollutant load received by a filter and potentially increase the maintenance interval duration. The BaySeparatorlm system (Figures 3 & 4) is an ideal hydrodynamic separator that removes sediments and floatables from stormwater runoff. Please contact your ADS representative for additional pre-treatment options. BAYFILTER SITE PLAN PLACEMENT Locating a BayFilter system on your site will be determined by giving consideration to several factors including: maintenance access, the unit's footprint, available head, available depth, and the surface elevation of the receiving waters. A BayFilter system must be installed in an area that is accessible to maintenance equipment. The maintenance of a BayFilter system requires a vacuum truck as well as the removal and replacement of the filter cartridges. The manhole covers, and or access hatches of the BayFilter must be placed in locations that can be easily reached by such a vehicle. Consult the BaySaver Technologies Engineering Department for expert assistance. Traditional BaySeparator Figure 3: Traditional BaySeparator Pre -Treatment Configuration OVERFLOW ",,,ON PIPE MANHOLE TREATMENT PIPE BAYSEPARATOR BAYFIL Figure 4: BaySeparator FS Unit Pre -Treatment Configuration W 4 BayFilter System Sizing Each BayFilter system relies on a collection of individual BayFilter cartridges to achieve the desired removal efficiency. Accurately determining the required number of filters is important to efficient operation. Undersizing a system may lead to shorten service life. A valuable stormwater treatment system will be provided when the three design parameters listed below are given consideration. Jurisdiction -specific sizing requirements Flow capacity of the system Treated sediment load of the system Each parameter results in a required number of BayFilter cartridges. After computing the number of filters for each parameter, determine which requires the most filters, and this is is the limiting design parameter and the number of required BayFilter cartridges for your drainage area. Jurisdiction Local regulatory requirements play a significant role in any BayFilter design. Depending on the jurisdiction in which the project site is located, the engineer may have to meet minimum treatment flow rates, treatment volumes or some other criteria such as filter bed area. Some jurisdictions specify a methodology for calculating a minimum treatment flow rate for a given site. Flow Capacity Regulatory requirements will determine water quality treatment values. The BayFilter system is simply applied by the design professional to their computed values. Typically, the primary treatment value is treatment flow rate (QTRT)' This value tells us the rate at which flow must pass through a filter system. Other common treatment values are water quality volume and phosphorous load reduction. Please contact BaySaver Technologies Engineering Department when designing to volume or phosphorous requirements. The minimum number of BayFilter cartridges can be determined by dividing the treatment flow rate by flow rate of the BayFilter you have chosen. This calculation provides the minimum number of BayFilters that will be necessary to fully treat the water quality flow from the site. The step-by-step procedure is shown below. BayFilter Series 500 System Sizing Table BayFilter Treatment Treatment Cartridge Flow Rate Volume gpm (1/min) f (m ) 522 22.5 (85.1) 1250 (35.4) 530 30.0 (113.6) 2500 (70.8) 545 45.0 (170.3) 2500 (70.8) BayFilter Series 600 System Sizing Table BayFilter Treatment Treatment Cartridge Flow Rate Volume gpm (1/min) f (m ) 622 22.5 (85.1) 1250 (35.4) 630 30.0 (113.6) 2500 (70.8) 645 45.0 (170.3) 2500 (70.8) Determine the required treatment flow rate (QTRT) based on locally approved methodologies for the project site. This may involve the use of the Rational Method, TR-55 or another locally specified hydrologic model. If a locally approved methodology is not specified, BaySaver Technologies recommends using one of these commonly accepted models. 2. Using the BayFilter cartridge treatment flow rate (QBayFilter)' calculate the minimum numbers of BayFilter cartridges required to treat that flow using Equation 1. Refer to the product details for BayFilter flow rates. The minimum number of BayFilter cartridges is equal to the maximum treatment flow rate divided by QBayFilter' rounded up to the next whole number. Sediment Load Capacity BayFilter sediment load capacity allows the professional designer to establish the maintenance interval for the stormwater system. Establishing a sediment load is a straight forward computation which may be completed once the number of BayFilter cartridges required to treat the flow is known. With the known filter quantity, a designer will establish the sediment load capacity for the BayFilter system, and compare this value to the annual sediment load for the site. The following equations may be used to compute these values and help determine BayFilter suitability for a specific site design. Sediment Load Capacity Calculations Calculate the annual treated runoff volume according to Equation 2. VTRT is the annual treated runoff volume, P is the average annual precipitation (in inches), A is the area of the site (in acres), c is the runoff coefficient of the site (c is dimensionless), and % Capture is the fraction of the total annual runoff that is treated by the stormwater quality system. If % Capture is not otherwise specified, a default value of 0.90 can be used. Please check local regulations. Using the annual treated runoff volume, calculate the anticipated total system sediment load to BayFilter according to Equation 3. In Equation 3, L is the mass of sediment that BayFilter is exposed to annually (in pounds), VTRT is the annual treated runoff volume as calculated in step 1 (in ft3), and TSS IN is the influent concentration of TSS in the runoff (in mg/L). The influent TSS concentration (TSS IN)depends greatly on the site and the surrounding land use. In the absence of readily available data, BaySaver Technologies recommends using a minimum event mean concentration (EMC) TSS value of 60 mg/I. The impact on the filter cartridge will also be less if # Cartridges = (c f s) x 448.8 9pm QTRT f Equation 1 vTRT Vt3) = PxAxcx ft12 in Equation 2 QBayFiiter 43,560 ft2 x %capture acre 28f.31t kg 2.21bs CL(lbs) = vTRT x TssL71 x J t3 x 106mg x kg Equation 3 the filtration system is preceded by pretreatment. In these cases, the influent TSS to the BayFilter system need to be reduced to reflect pretreatment sediment removal. The BaySaver Technologies' Engineering Department can assist with these calculations. 3. Once the total annual system sediment load (L) is calculated, the engineer must ensure that the number of cartridges specified will be able to remove that sediment load at the specified design flow rate. Divide the total system sediment load L by the capacity of each BayFilter and note the associated BayFilter flow rate. Round up to the next whole number to get the minimum number of BayFilters required. This quantity of BayFilters will need to treat this sediment load at the required flow rate per BayFilter. The BaySaver Technologies Engineering Department is available to assist with the required calculations. FINAL CHECK It may be beneficial to perform a Final Check on the BayFilter design for your site. The BaySaver Engineering Department is available to assist you with this function. Standard Details and Notes Standard details are available on the Website at www.BaySaver.com or by calling 1.800.229.7283. BayFilter Configurations BayFilter Systems include the four typical concrete structures: manhole, precast vault, box culvert, and cast in place. BaySaver Technologies can also design BayFilter systems with Nyloplast structures, and HP Pipe manholes. BayFilter systems in manholes have a small footprint and easily fit into site plans. Manhole BayFilter systems are ideal for applications downstream from water quality detention structures. Please consult with the BaySaver Technologies Engineering Department for more details. When designing access for a BayFilter utilizing manhole frame and covers a minimum of 30" (762) diameter should be used, however, it is recommended that a 36" (914) diameter opening is used to provide ample access for filter replacement and maintenance. In each BayFilter system, the BayFilters are arranged so that a maintenance worker can stand on the floor of the manhole while installing or removing the cartridges. Example of a manhole BayFilter system Example of a precast vault BayFilter system INSTALLATION Note: BayFilters are not recommended to be used as erosion control during site construction operations. BayFilters should remain offline or uninstalled until site stabilization has occurred. Please contact your local ADS or BaySaver representative if you should have any questions. 1. Contact utility locator to mark any nearby underground utilities and make sure it is safe to excavate. 2. Reference the site plan and stake out the location of the BayFilter manhole/vault. 3. Excavate the hole, providing any sheeting and shoring necessary to comply with all federal, state and local safety regulations. 4. Level the subgrade to the proper elevation. Verify the elevation against the manhole/vault dimensions, the invert elevations, and the site plans. Adjust the base aggregate, if necessary. 5. Have the soil bearing capacity verified by a licensed engineer for the required load bearing capacity. On solid subgrade, set the first section of the BayFilter manhole/ vault. 6. Check the level and elevation of the first section to ensure it is correct before adding any riser sections. 7. If additional section(s) are required, add a watertight seal to the first section of the BayFilter manhole/vault. Set additional section(s) of the manhole/vault, adding a watertight seal to each joint. 8. Install the outlet pipe in BayFilter manhole/vault. 9. Install the inlet pipe to the BayFilter manhole/vault. 10. Install the trolley system (if applicable). a. Attach the mounting brackets to the track. b. Each track is split in sections. The length and number of sections vary depending on the vault. It is generally better to start installing longer track sections first. Hold a section in place and align the top of the brackets with the ceiling of the vault. Mark the center of the hole in each bracket and remove the track. c. Using a hammer drill and (6 mm) bit, drill a hole approximately 3" (76 mm) deep at each mark. d. Hold the track back in place and realign the brackets with the holes. Place a plastic spacer block behind each bracket and using the supplied'/4" (6 mm) x 3'/4" (83 mm) anchor bolts mount the track in place. Only install one section of track at this stage. Modular Vault Assembly 00, Vault End Section r- e 4 rolley System ab e. Repeat this procedure on the opposite wall of the vault directly across from the first section. f. Bolt the 4 trolleys to the aluminum I-beam as shown in the attached diagram. Make sure that the wheels for each trolley are mounted an equal distance from the top of the I-beam. g. Lift the I-beam in to place and insert the trolleys in to the track. h. Using the supplied couplers, install the second sections of track via the same procedure. Continue until the track runs the length of the vault or as designed. 11. Install the PVC manifold. Glue all PVC joints with the exception of the BayFilter cartridge coupling. See Parts List drawing. 12. After the site has stabilized, remove any accumulated sediment or debris from the vault. 13. Install the Bayfilter Vertical Drain Down Modules (VDDM) to the manifold system (if applicable). 14. Install a row of flow disks and the BayFilter cartridges. Place each cartridge so the handle points across the vault. Make sure the air valve is on the side closer to the outlet. 15. Place one full set of one Hold Down Bar and two Retainer Brackets into place. Mark and drill two 5/8" holes for each bracket. After fully anchoring Retainer Brackets, place the left end of the Hold Down Bar in position. Slide right end into bracket and secure with U-Bolt. 16. Repeat steps 14 and 15 for each set of BayFilter Cartridges and Hold Down Bar until the whole system is installed. See Parts List drawing for Hold Down Bar placement. Tool List • PVC glue and primer • Crane/lifting mechanism to lower the cartridges in the vault (each cartridge weighs 230-350 Ibs (104-159)) • Screwdriver or nut driver for Fernco° couplers • Hammer and soft blow hammer • Saw (in case PVC Sch 40 piping length needs to be adjusted) • Hammer drill • '/4" (6 mm) and 5/8" (16 mm) concrete drill bit • 3/4" (19 mm) wrench Filter Tee Flow Disc Drain Down Module Filter Placement jog Hold Down Bar Chain Hoist System and Bracket BayFilter Vault Overview Vault Internal Assembly Pre -Assembled Manifold In some areas the vaults can be provided with pre -in- stalled manifold systems. Please contact your local ADS or BaySaver representatives for additional details. Inspection and Maintenance The BayFilter system requires periodic maintenance to continue operating at the design efficiency. The maintenance process is comprised of the removal and replacement of each BayFilter cartridge, vertical drain down module; and the cleaning of the vault or manhole with a vacuum truck. The maintenance cycle of the BayFilter system will be driven mostly by the actual solids load on the filter. The system should be periodically monitored to be certain it is operating correctly. Since stormwater solids loads can be variable, it is possible that the maintenance cycle could be more or less than the projected duration. BayFilter systems in volume -based applications are designed to treat the WQv in 24 to 48 hours initially. Late in the operational cycle of the BayFilter, the flow rate will diminish as a result of occlusion. When the drain down exceeds the regulated standard, maintenance should be performed. When a BayFilter system is first installed, it is recommended that it be inspected every six (6) months. When the filter system exhibits flows below design levels the system should be maintained. Filter cartridge replacement should also be considered when sediment levels are at or above the level of the manifold system. Please contact the BaySaver Technologies Engineering Department for maintenance cycle estimations or assistance at 1.800.229.7283. Maintenance Procedures 1. Contact BaySaver Technologies for replacement filter cartridge pricing and availability at 1-800-229-7283. 2. Remove the manhole covers and open all access hatches. 3. Before entering the system make sure the air is safe per OSHA Standards or use a breathing apparatus. Use low 02' high CO, or other applicable warning devices per regulatory requirements. 4. Using a vacuum truck remove any liquid and sediments that can be removed prior to entry. 5. Using a small lift or the boom of the vacuum truck, remove the used cartridges by lifting them out. 6. Any cartridges that cannot be readily lifted can be easily slid along the floor to a location BayFilter System Cleanout Vactor Truck Maintenance Jet Vactoring Through Access Hatch they can be lifted via a boom lift. 7. When all the cartridges have been removed, it is not practical to remove the balance of the solids and water. Loosen the stainless clamps on the Fernco couplings for the manifold and remove the drain pipes as well. Carefully cap the manifold and the Ferncos and rinse the floor, washing away the balance of any remaining collected solids. 8. Clean the manifold pipes, inspect, and reinstall. 9. Install the exchange cartridgess and close all covers. 10. The used cartridges may be sent back to BaySaver Technologies for recycling. BayFilter Availability and Cost BayFilter systems are available throughout the United States from BaySaver Technologies. Material, installation, and maintenance costs vary with location. For BayFilter pricing in your area, please contact BaySaver Technologies at 1-800-229-7283. BayFilter cartridges and outlet components can be shipped anywhere in the world. Manholes and precast vaults are also supplied by BaySaver Technologies as part of a complete stormwater filtration system. BayFilter Specifications Products A. Internal components: all components including concrete structure(s), PVC manifold piping and filter cartridges, shall be provided by BaySaver Technologies 1-800-229-7283). B. PVC manifold piping: all internal PVC pipe and fittings shall meet ASTM D1785. Manifold piping shall be provided to the contractor pre-cut and/or pre - assembled. Minor field modifications may be necessary. C. Filter cartridges: external shell of the filter cartridges shall be substantially constructed of polyethylene or equivalent material acceptable to the manufacturer. Filtration media shall be arranged in a spiral layered fashion to maximize available filtration area. An orifice flow control (i.e. flow disk) shall be supplied with each cartridge to restrict the flow rate to a maximum of 45 gpm (170 I/min). D. Filter media: filter media shall be a proprietary mix produced by BaySaver Technologies and may consist of the following materials: zeolite, perlite, and activated alumina and/or other materials required to meet the project pollutant removal requirements. Manifold Tee View of a Cleaned System Cartridge Hoist Point E. Precast concrete vault: concrete structures shall be provided according to ASTM C478, C858, and C913. The materials and structural design of the devices shall be per ASTM C478 and ACI 318. Precast concrete shall be provided by BaySaver Technologies. Performance A. The stormwater filter system shall be capable of treating 100% of the required treatment flow at full sediment load conditions. B. The stormwater filter system's cartridges shall have no moving parts. C. The stormwater treatment unit shall be designed to remove a minimum of 80% of suspended solids, 60% of total phosphorus, 50% of turbidity, 40% of total copper, and 40% of total zinc. All filter designs shall comply with local regulations. D. The stormwater filtration system shall not have any components that leach nitrates, phosphates or metals. E. The stormwater filtration cartridge shall be equipped with a hydrodynamic backwash mechanism to extend the filter's life and optimize its performance. F. The stormwater filtration system's cartridges shall have a treated sediment capacity for 80% TSS removal between 150-350 Ibs (68-159 kg). When BayFilter is initially installed, we recommend that an inspection be performed on the system in the first six (6) months. After that, the inspection cycle typically falls into an annual pattern given normal storm occurrence and actual solids loads. When BayFilter exhibits flows below design levels, the system should be inspected and maintained as soon as practical. If flow monitoring is not available, BayFilter cartridges should be replaced when sediment levels are at or above the top of the manifold. ADS "Terms and Conditions of Sale" are available on the ADS website, www.ads-pipe.com The ADS logo and the Green Stripe are registered trademarks of Advanced Drainage Systems, Inc. BayFilter' is a registered trademark of BaySaverTechnologies, Inc. © 2018 Advanced Drainage Systems, Inc. #10951 01/18 MH 'A14 ULAJO THE MOST ADVANCED NAME IN WATER MANAGEMENT SOLUTIONSTM LLLLL�' 1-800-821-6710 www.ads-pipe.com 1-800-229-7283 www.baysaver.com 7latorlo HC n&m O� 1 � r FLAMP 0 9MM' - u��ttt� THE ISOLATOR° ROW PLUS INTRODUCTION An important component of any Stormwater Pollution Prevention Plan is inspection and maintenance. The StormTech Isolator Row PLUS is a technique to inexpensively enhance Total Suspended Solids (TSS) and Total Phosphorus (TP) removal with easy access for inspection and maintenance. THE ISOLATOR ROW PLUS The Isolator Row PLUS is a row of StormTech chambers, either SC-160, SC-310, SC-310-3, SC-740, DC-780, MC-3500 or MC-4500 models, that is surrounded with filter fabric and connected to a closely located manhole for easy access. The fabric -wrapped chambers provide for settling and filtration of sediment as storm water rises in the Isolator Row PLUS and ultimately passes through the filter fabric. The open bottom chambers and perforated sidewalls (SC-310, SC- 310-3 and SC-740 models) allow storm water to flow both vertically and horizontally out of the chambers. Sediments are captured in the Isolator Row PLUS protecting the storage areas of the adjacent stone and chambers from sediment accumulation. ADS geotextile fabric is placed between the stone and the Isolator Row PLUS chambers. The woven geotextile provides a media for stormwater filtration, a durable surface for maintenance, prevents scour of the underlying stone and remains intact during high pressure jetting. A non- woven fabric is placed over the chambers to provide a filter media for flows passing through the perforations in the sidewall of the chamber. The non- woven fabric is not required over the SC-160, DC-780, MC-3500 or MC- 4500 models as these chambers do not have perforated side walls. The Isolator Row PLUS is designed to capture the "first flush" runoff and offers the versatility to be sized on a volume basis or a flow -rate basis. An upstream manhole not only provides access to the Isolator Row PLUS but includes a high/low concept such that stormwater flow rates or volumes that exceed the capacity of the Isolator Row PLUS bypass through a manifold to the other chambers. This is achieved with either an elevated bypass manifold or a high -flow weir. This creates a differential between the Isolator Row PLUS row of chambers and the manifold to the rest of the system, thus allowing for settlement time in the Isolator Row PLUS. After Stormwater flows through the Isolator Row PLUS and into the rest of the StormTech chamber system it is either exfiltrated into the soils below or passed at a controlled rate through an outlet manifold and outlet control structure. The Isolator Row FLAMPTm (patent pending) is a flared end ramp apparatus that is attached to the inlet pipe on the inside of the chamber end cap. The FLAMP provides a smooth transition from pipe invert to fabric bottom. It is configured to improve chamber function performance overtime by enhancing outflow of solid debris that would otherwise collect at an end of the chamber. It also serves to improve the fluid and solid flow into the access pipe during maintenance and cleaning and to guide cleaning and inspection equipment back into the inlet pipe when complete. The Isolator Row PLUS may be part of a treatment train system. The design of the treatment train and selection of pretreatment devices by the design engineer is often driven by regulatory requirements. Whether pretreatment is used or not, the Isolator Row PLUS is recommended by StormTech as an effective means to minimize maintenance requirements and maintenance costs. Note: See the StormTech Design Manual for detailed information on designing inlets for a StormTech system, including the Isolator Row PLUS. Looking down the Isolator Row PLUS from the manhole opening, ADS PLUS Fabric is shown between the chamber and stone base. StormTech Isolator Row PLUS with Overflow Spillway (not to scale) ISOLATOR ROW PLUS INSPECTION/MAINTENANCE INSPECTION The frequency of inspection and maintenance varies by location. A routine inspection schedule needs to be established for each individual location based upon site specific variables. The type of land use (i.e. industrial, commercial, residential), anticipated pollutant load, percent imperviousness, climate, etc. all play a critical role in determining the actual frequency of inspection and maintenance practices. At a minimum, StormTech recommends annual inspections. Initially, the Isolator Row PLUS should be inspected every 6 months for the first year of operation. For subsequent years, the inspection should be adjusted based upon previous observation of sediment deposition. The Isolator Row PLUS incorporates a combination of standard manhole(s) and strategically located inspection ports (as needed). The inspection ports allow for easy access to the system from the surface, eliminating the need to perform a confined space entry for inspection purposes. If upon visual inspection it is found that sediment has accumulated, a stadia rod should be inserted to determine the depth of sediment. When the average depth of sediment exceeds 3 inches throughout the length of the Isolator Row PLUS, clean -out should be performed. MAINTENANCE The Isolator Row PLUS was designed to reduce the cost of periodic maintenance. By "isolating" sediments to just one row, costs are dramatically reduced by eliminating the need to clean out each row of the entire storage bed. If inspection indicates the potential need for maintenance, access is provided via a manhole(s) located on the end(s) of the row for cleanout. If entry into the manhole is required, please follow local and OSHA rules for a confined space entries. Maintenance is accomplished with the JetVac process. The JetVac process utilizes a high pressure water nozzle to propel itself down the Isolator Row PLUS while scouring and suspending sediments. As the nozzle is retrieved, the captured pollutants are flushed back into the manhole for vacuuming. Most sewer and pipe maintenance companies have vacuum/JetVac combination vehicles. Selection of an appropriate JetVac nozzle will improve maintenance efficiency. Fixed nozzles designed for culverts or large diameter pipe cleaning are preferable. Rear facing jets with an effective spread of at least 45" are best. StormTech recommends a maximum nozzle pressure of 2000 psi be utilized during cleaning. Most JetVac reels have 400 feet of hose allowing maintenance of an Isolator Row PLUS up to 50 chambers long. The JetVac process shall only be performed on StormTech Isolator Row PLUS that have ADS PLUS Fabric (as specified by StormTech) over their angular base stone. StormTech Isolator Row PLUS (not to scale) Note: Non -woven fabric is only required over the inlet pipe connection into the end cap for SC-160LP, DC-780, MC-3500 and MC-4500 chamber models and is not required over the entire Isolator Row PLUS. BAGKF,LL MATERL COVER ENTIRE ISOLATOR ROW WITH ADS DEOSYNTHETICS SWT 4044MEN DEOTE%TILE W (2A m) MIN WIDE ELEVATED BYPASS MMIFOLD SUMP DEPTH TED BY CATCH BASIN SITE DESIGN ENGINEER OR MANHOLE [24' [BBB ..) MIN RECOMMENDED[ SC-74 CHAMBEl 24' ISODm.. HDPE ACCESS PIPE REQUIRED USE FACTORY PREFABRICATED END CAP WITH FLAMIP PART N; $CT4pEPE74BR $G746 END CAP JEOTVXTI l E 9ETWEEN FOLINDAT ION STONE ANO CHAMBERS S 0.5 m) MIN WIDE CONTINUOUS FIERIC WITHOUT SEAMS ISOLATOR ROW PLUS STEP BY STEP MAINTENANCE PROCEDURES STEP 1 Inspect Isolator Row PLUS for sediment. A) Inspection ports (if present) i. Remove lid from floor box frame ii. Remove cap from inspection riser iii. Using a flashlight and stadia rod,measure depth of sediment and record results on maintenance log. iv. If sediment is at or above 3 inch depth, proceed to Step 2. If not, proceed to Step 3. B) All Isolator Row PLUS i. Remove cover from manhole at upstream end of Isolator Row PLUS ii. Using a flashlight, inspect down Isolator Row PLUS through outlet pipe 1. Mirrors on poles or cameras may be used to avoid a confined space entry 2. Follow OSHA regulations for confined space entry if entering manhole iii. If sediment is at or above the lower row of sidewall holes (approximately 3 inches), proceed to Step 2. If not, proceed to Step 3. STEP 2 Clean out Isolator Row PLUS using the JetVac process. A) A fixed floor cleaning nozzle with rear facing nozzle spread of 45 inches or more is preferable B) Apply multiple passes of JetVac until backflush water is clean C) Vacuum manhole sump as required STEP 3 Replace all caps, lids and covers, record observations and actions. STEP 4 Inspect & clean catch basins and manholes upstream of the StormTech system. SAMPLE MAINTENANCE LOG 3/16111 6.3 fE KOKe New LKAolLaELoK, FLxed poLKE Ls C1 frame aE DOM grade V24/11 6.2 0.1 f E Some 9KE f eLE SM 6/20/13 S.Fr 0.6 f E Mucky feel. debrLs vULble LK makkole aKcl EK NV IsoLokor tow ?LOS, maCkEekaHce due 7/7/13 6.3 f E o 54SEerA , jeRed w►od vacuumed DW STORMTECH DC-780 CHAMBER Designed to meet the most stringent industry performance standards for structural integrity while providing designers with a cost-effective method valuable land and protect water resources. The StormTech system is desi€ primarily to be used under parking lots, thus maximizing land usage for prl (commercial) and public applications. , thus enhancing the performance extending the service life of these practices. • 12' (3.6 m) Deep Cover Applications • Designed in accordance with ASTM F 2787 and produced to meet the ASTM 2418 product standard. • AASHTO safety factors provided for AASHTO Design Truck (1-120 and deep cover conditions.) STORMTECH DC-780 CHAMBER (not to scale) Nominal Chamber Specifications Size (LxWxH) 85.4" x 51.0" x 30.0" 2,170 mm x 1,295 mm x 762 mm Chamber Storage 46.2 ft3 (1.30 m3) Min. Installed Storage* 78.4 ft3 (2.20 m3) Weight 80.0 Ibs (36.3 kg) Shipping 24 chambers/pallet 60 end caps/pallet 12 pallets/truck *Assumes 9" (230 mm) stone below, 6" (150 mm) row spacing and 40%stone porosity. EMBEDMENT STONE SHALL BE A CLEAN, CRUSHED AND ANGULAR STONE WITH AN AASHTO M43 DESIGNATION BETWEEN #3 AND #57 CHAMBERS SHALL MEET ASTM F2418 "STANDARD SPECIFICATION FOR POLVPROPLENE (PP) CORRUGATED WALL STORMWATER COLLECTION CHAMBERS'. ADS GEOSVTHETICS 601T NON -WOVEN GEOTEXTILE ALL AROUND CLEAN, CRUSHED, ANGULAR EMBEDMENT STONE 90.7" (2304 mm) ACTUAL LENGTH 30.0" (762 mm) 51.0" (1295 mm) GRANULAR WELL -GRADED SOIUAGGREGATE MIXTURES, 135% FINES, COMPACT IN s" (159 mm) MAX LIFTS TO 95%PROCTOR DENSITY. SEE THE TABLE OF ACCEPTABLE FILL MATERIALS. CHAMBERS SHALL BE BE DESIGNED IN ACCORDANCE WITH ASTM F2787 'STANDARD PRACTICE FOR STRUCTURAL DESIGN OF THERMOPLASTIC CORRUGATED WALL STORMWATER COLLECTION CHAMBERS'. PAVEMENT LAYER(DESIGNED BY SITE DESIGN ENGINEER) PERIMETERSTONE EXCAVATION L (CAN BE SLOPED OR VERTICAL) III •� -I�.rI I— - — DEPTH OF STONE TO BE DETERMINED — III -III Ili11 IL �L II T}�Ll�it Lfll�iL4 �I �I—I�I'[Ii L BY SITE DESIG N ENG INEER 9-(239m)MIN Ir Ill III 12" (399 mm) MIN S1]40/DC-]89 END CAP 9 1205 mm) "(399 mm) SITE DESIGN ENGINEER IS RESPONSIBLE FOR (159 mm) MIN 51-(12 TVP THE ENSURING THE REQUIRED BEARING CAPACITY OF SUBGRADE SOILS 'MINIMUM COVER TO BOTTOM OF FLEXIBLE PAVEMENT. FOR UNPAVED INSTALLATIONS WHERE RUTTING FROM VEHICLES MAY OCCUR, INCREASE COVER TO 24- (s99 mm). DC-780 CUMULATIVE STORAGE VOLUMES PER CHAMBER Assumes 40% Stone Porosity. Calculations are Based Upon a 9" (230 mm) Stone Base Under Chambers. Depth Inches (mm) 45 (1,143) StorageSystem 46.27 (1.310) Storage 78.47 (2.222) 44 (1,118) 46.27 (1.310) 77.34 (2.190) 43 (1,092) Stone 46.27 (1.310) 76.21 (2.158) 42 (1,067) Cover 46.27 (1.310) 75.09 (2.126) 41 (1,041) 46.27 (1.310) 73.96 (2.094) 40 (1,016) 46.27 (1.310) 72.83 (2.062) 39 (991) 46.27 (1.310) 71.71 (2.030) 38 (965) 46.21 (1.309) 70.54 (1.998) 37 (940) 46.04 (1.304) 69.32 (1.963) 36 (914) 45.76 (1.296) 68.02 (1.926) 35 (889) 45.15 (1.278) 66.53 (1.884) 34 (864) 44.34 (1.255) 64.91 (1.838) 33 (838) 43.38 (1.228) 63.21 (1.790) 32 (813) 42.29 (1.198) 61.43 (1.740) 31 (787) 41.11 (1.164) 59.59 (1.688) 30 (762) 39.83 (1.128) 57.70 (1.634) 29 (737) 38.47 (1.089) 55.76 (1.579) 28 (711) 37.01 (1.048) 53.76 (1.522) 27 (686) 35.49 (1.005) 51.72 (1.464) 26 (660) 33.90 (0.960) 49.63 (1.405) 25 (635) 32.24 (0.913) 47.52 (1.346) 24 (610) 30.54 (0.865) 45.36 (1.285) 23 (584) 28.77 (0.815) 43.18 (1.223) 22 (559) 26.96 (0.763) 40.97 (1.160) 21 (533) 25.10 (0.711) 38.72 (1.096) 20 (508) 23.19 (0.657) 36.45 (1.032) 19 (483) 21.25 (0.602) 34.16 (0.967) 18 (457) 19.26 (0.545) 31.84 (0.902) 17 (432) 17.24 (0.488) 29.50 (0.835) 16 (406) 15.19 (0.430) 27.14 (0.769) 15 (381) 13.10 (0.371) 24.76 (0.701) 14 (356) 10.98 (0.311) 22.36 (0.633) 13 (330) 8.83 (0.250) 19.95 (0.565) 12 (305) 6.66 (0.189) 17.52 (0.496) 11 (279) 4.46 (0.126) 15.07 (0.427) 10 (254) 2.24 (0.064) 12.61(0- Depth of Water in Inches (mm) 9 (229) Cumulative Chamber StorageSystem o(o) Total System Cumulative Storage 10.14 (0.287) 8 (203) o(o) 9.01 (0.255) 7 (178) o(o) 7.89 (0.223) 6 (152) Stone Foundation o(o) o(o) 6.76 (0.191) 5 (127) 5.63 (0.160) 4 (102) o(o) 4.51 (0.128) 3 (76) o(o) 3.38 (0.096) o(o) 2.25 (0.064) 0 (0) 1.13 (0.032) 2 (51) 1 (25) Note: Add 1.13 ft3 (0.032 ml) of Storage for Each Additional Inch (25 mm) of Stone Foundation. STORAGEVOLUME PER CHAMBER FT3 (M3) �Mamber and Stone 1W �•Foundation Depth I II 11 11I DC-780 Cham"7.4 1 78.4 (2.2) 1 81.8 (2.3) Note: Assumes 40% porosity for the stone, the bare chamber volume, 6" (150 mm) of stone above, and 6" (150 mm) row spacing. AMOUNT OFSTONE PER CHAMBER FDC 1 � -780 Chamber 4.2 (3.0) 4.7 (3.3) "(3.9) KILOGRAMSMETRIC I mm 300 mm 450 mm DC-780 Chamber 3,810 (2.3) 1 4,264 (2.5) 5,080 (3.0) Note: Assumes 9" (150 mm) of stone above, and between chambers. VOLUME EXCAVATION PER CHAMBER YD3 (M3 1111' stone Foundation 1 I II I DC-780 Chamber 5.9 (4.5) 6.3 (4.8) 6.9 (5.3) Note: Assumes 6" (150 mm) separation between chamber rows and 18" (450 mm) of cover. The volume of excavation will vary as depth of cover increases. Working on a project? DDS i G N Visit us at www.stormtech.com TOO and utilize the StormTech Design Tool For more information on the StormTech DC-780 Chamber and other ADS products, please contact our Customer Service Representatives at 1-800-821.6710 ACCEPTABLE FILL MATERIALS: STORMTECH DC-780 CHAMBER SYSTEMS AASHTO MATERIAL MATERIAL LOCATION DESCRIPTION COMPACTION / DENSITY REQUIREMENT CLASSIFICATIONS FINAL FILL: FILL MATERIAL FOR LAYER'D' STARTS FROM THE PREPARE PER SITE DESIGN ENGINEER'S PLANS. PAVED D TOP OF THE'C' LAYER TO THE BOTTOM OF FLEXIBLE ANY SOIL/ROCK MATERIALS, NATIVE SOILS, OR PER ENGINEER'S PLANS. N/A INSTALLATIONS MAY HAVE STRINGENT MATERIAL AND PAVEMENT OR UNPAVED FINISHED GRADE ABOVE. NOTE THAT CHECK PLANS FOR PAVEMENT SUBGRADE REQUIREMENTS. PREPARATION REQUIREMENTS. PAVEMENT SUBBASE MAY BE PART OF THE'D' LAYER AASHTO M145' BEGIN COMPACTIONS AFTER 12" (300 mm) OF MATERIAL OVER GRANULAR WELL -GRADED SOIL/AGGREGATE MIXTURES, <35% FINES OR A-1, A-24, A-3 THE CHAMBERS IS REACHED. COMPACT ADDITIONAL LAYERS IN INITIAL FILL: FILL MATERIAL FOR LAYER'C' STARTS FROM THE PROCESSED AGGREGATE. 6" (150 mm) MAX LIFTS TO A MIN. 95% PROCTOR DENSITY FOR C TOP OF THE EMBEDMENT STONE ('B' LAYER) TO 18" (450 mm) OR WELL GRADED MATERIAL AND 95% RELATIVE DENSITY FOR ABOVE THE TOP OF THE CHAMBER. NOTE THAT PAVEMENT MOST PAVEMENT SUBBASE MATERIALS CAN BE USED IN LIEU OF THIS PROCESSED AGGREGATE MATERIALS. ROLLER GROSS SUBBASE MAY BE A PART OF THE'C' LAYER. LAYER. AASHTO M43 VEHICLE WEIGHT NOT TO EXCEED 12,000 Ibs (53 kN). DYNAMIC 3, 357, 4, 467, 5, 56, 57, 6, 67, 68, 7, 78, 8, 89, 9, 10 FORCE NOT TO EXCEED 20,000 Ibs (89 kN). EMBEDMENT STONE: FILL SURROUNDING THE CHAMBERS AASHTO M43' B FROM THE FOUNDATION STONE ('A' LAYER) TO THE'C' LAYER CLEAN, CRUSHED, ANGULAR STONE 3, 357, 4, 467, 5, 56, 57 NO COMPACTION REQUIRED. ABOVE. A FOUNDATION STONE: FILL BELOW CHAMBERS FROM THE CLEAN, CRUSHED, ANGULAR STONE AASHTO M43' PLATE COMPACT OR ROLL TO ACHIEVE A FLAT SURFACE23 SUBGRADE UP TO THE FOOT (BOTTOM) OF THE CHAMBER. 3, 357, 4, 467, 5, 56, 57 PLEASE NOTE: 1. THE LISTED AASHTO DESIGNATIONS ARE FOR GRADATIONS ONLY. THE STONE MUST ALSO BE CLEAN, CRUSHED, ANGULAR. FOR EXAMPLE, A SPECIFICATION FOR #4 STONE WOULD STATE: "CLEAN, CRUSHED, ANGULAR NO. 4 (AASHTO M43) STONE". 2. STORMTECH COMPACTION REQUIREMENTS ARE MET FORA' LOCATION MATERIALS WHEN PLACED AND COMPACTED IN 9" (230 mm) (MAX) LIFTS USING TWO FULL COVERAGES WITH A VIBRATORY COMPACTOR. 3. WHERE INFILTRATION SURFACES MAY BE COMPROMISED BY COMPACTION, FOR STANDARD DESIGN LOAD CONDITIONS, A FLAT SURFACE MAY BE ACHIEVED BY RAKING OR DRAGGING WITHOUT COMPACTION EQUIPMENT. FOR SPECIAL LOAD DESIGNS, CONTACT STORMTECH FOR COMPACTION REQUIREMENTS. 4. ONCE LAYER'C' IS PLACED. ANY SOIL/MATERIAL CAN BE PLACED IN LAYER'D' UP TO THE FINISHED GRADE. MOST PAVEMENT SUBBASE SOILS CAN BE USED TO REPLACE THE MATERIAL REQUIREMENTS OF LAYER 'C' OR'D' AT THE SITE DESIGN ENGINEER'S DISCRETION. PERIMETER STONE (SEE NOTE 4) ADS GEOSYNTHETICS 601T NON -WOVEN GEOTEXTILE ALL AROUND CLEAN, CRUSHED, ANGULAR STONE IN A & B LAYERS PAVEMENT LAYER (DESIGNED BY SITE DESIGN ENGINEER) 1 EXCAVATION WALL (CAN BE SLOPED OR VERTICAL) 12" (300 1 SUBGRADE SOILS (SEE NOTE 3) 6" (150 mm) MIN NOTES: 1. CHAMBERS SHALL MEET THE REQUIREMENTS OF ASTM F2418-16a, "STANDARD SPECIFICATION FOR POLYPROPYLENE (PP) CORRUGATED WALL STORMWATER COLLECTION CHAMBERS". 2. DC-780 CHAMBERS SHALL BE DESIGNED IN ACCORDANCE WITH ASTM F2787 "STANDARD PRACTICE FOR STRUCTURAL DESIGN OF THERMOPLASTIC CORRUGATED WALL STORMWATER COLLECTION CHAMBERS". 3. THE SITE DESIGN ENGINEER IS RESPONSIBLE FOR ASSESSING THE BEARING RESISTANCE (ALLOWABLE BEARING CAPACITY) OF THE SUBGRADE SOILS AND THE DEPTH OF FOUNDATION STONE WITH CONSIDERATION FOR THE RANGE OF EXPECTED SOIL MOISTURE CONDITIONS. 4. PERIMETER STONE MUST BE EXTENDED HORIZONTALLY TO THE EXCAVATION WALL FOR BOTH VERTICAL AND SLOPED EXCAVATION WALLS. 5. REQUIREMENTS FOR HANDLING AND INSTALLATION: • TO MAINTAIN THE WIDTH OF CHAMBERS DURING SHIPPING AND HANDLING, CHAMBERS SHALL HAVE INTEGRAL, INTERLOCKING STACKING LUGS. • TO ENSURE A SECURE JOINT DURING INSTALLATION AND BACKFILL, THE HEIGHT OF THE CHAMBER JOINT SHALL NOT BE LESS THAN 2". • TO ENSURE THE INTEGRITY OF THE ARCH SHAPE DURING INSTALLATION, a) THE ARCH STIFFNESS CONSTANT AS DEFINED IN SECTION 6.2.8 OF ASTM F2418 SHALL BE GREATER THAN OR EQUAL TO 550 LBS/IN/IN. AND b) TO RESIST CHAMBER DEFORMATION DURING INSTALLATION AT ELEVATED TEMPERATURES (ABOVE 73° F / 23° C), CHAMBERS SHALL BE PRODUCED FROM REFLECTIVE GOLD OR YELLOW COLORS. 12' (3.7 m) MAX DEPTH OF STONE TO BE DETERMINED BY SITE DESIGN ENGINEER 9" (230 mm) MIN C) 00 U 0 0 w > C,J O m M Z� < _ 2O w < O J C J V2 z O Y Y U o LU w U) z Y U) Q W O a U rn 0 � o 0 o Z U) U w � O < a a 0 SHEET 1 of 1 DC-780 TECHNICAL SPECIFICATION NTS r- 90.7" (2304 mm) ACTUAL LENGTH I r85,4" (2169 mm) INSTALLED LENGTH a BUILD ROW IN THIS DIRECTION OVERLAP NEXT CHAMBER HERE (OVER SMALL CORRUGATION) ACCEPTS 4" (100 mm) SCH 40 PVC PIPE FOR INSPECTION PORT. FOR PIPE SIZES LARGER THAN 4" (100 mm) UP TO 10" (250 mm) USE INSERTA TEE CONNECTION CENTERED ON A CHAMBER CREST CORRUGATION START END NOMINAL CHAMBER SPECIFICATIONS SIZE (W X H X INSTALLED LENGTH) 51.0" X 30.0" X 85.4" (1295 mm X 762 mm X 2169 mm) CHAMBER STORAGE 46.2 CUBIC FEET (1.30 ml) MINIMUM INSTALLED STORAGE` 78.4 CUBIC FEET (2.20 ml) WEIGHT 75.0 lbs. (33.6 kg) 'I `ASSUMES 6" (152 mm) STONE ABOVE, 9" (229 mm) BELOW, AND 6" (152 mm) BETWEEN CHAMBERS JB 1 STUBS AT BOTTOM OF END CAP FOR PART NUMBERS ENDING WITH "B" C STUBS AT TOP OF END CAP FOR PART NUMBERS ENDING WITH "T" PART # STUB A B C SC740EPE06T / SC740EPE06TPC 6" (150 mm) 10.9" (277 mm) 18.5" (470 mm) --- SC740EPE06B / SC740EPE06BPC --- 0.5" (13 mm) SC740EPE08T / SC740EPE08TPC 8" (200 mm) 12.2" (310 mm) 16.5" (419 mm) --- SC740EPE08B / SC740EPE08BPC --- 0.6" (15 mm) SC740EPE10T / SC740EPE10TPC 10" (250 mm) 13.4" (340 mm) 14.5" (368 mm) --- SC740EPE10B / SC740EPE10BPC --- 0.7" (18 mm) SC740EPE12T / SC740EPE12TPC 12" (300 mm) 14.7" (373 mm) 12.5" (318 mm) --- SC740EPE12B / SC740EPE12BPC --- 1.2" (30 mm) SC740EPE15T / SC740EPE15TPC 15" (375 mm) 18.4" (467 mm) 9.0" (229 mm) SC740EPE15B / SC740EPE15BPC --- 1.3" (33 mm) SC740EPE18T/ SC740EPE18TPC 18" (450 mm) 19.7" (500 mm) 5.0" (127 mm) --- SC740EPE18B / SC740EPE18BPC --- 1.6" (41 mm) SC740EPE24B` 24" (600 mm) 18.5" (470 mm) --- 0.1" (3 mm) ALL STUBS, EXCEPT FOR THE SC740EPE24B ARE PLACED AT BOTTOM OF END CAP SUCH THAT THE OUTSIDE DIAMETER OF THE STUB IS FLUSH WITH THE BOTTOM OF THE END CAP. FOR ADDITIONAL INFORMATION CONTACT STORMTECH AT 1-888-892-2694. FOR THE SC740EPE24B THE 24" (600 mm) STUB LIES BELOW THE BOTTOM OF THE END CAP APPROXIMATELY 1.75" (44 mm). BACKFILL MATERIAL SHOULD BE REMOVED FROM BELOW THE N-12 STUB SO THAT THE FITTING SITS LEVEL. NOTE: ALL DIMENSIONS ARE NOMINAL OPTIONAL: COVER ENTIRE ISOLATOR ROW PLUS WITH ADS GEOSYNTHETICS 601T NON -WOVEN GEOTEXTILE 8' (2.4 m) MIN WIDE STORMTECH HIGHLY RECOMMENDS FLEXSTORM INSERTS IN ANY UPSTREAM STRUCTURES WITH OPEN GRATES ELEVATED BYPASS MANIFOLD SUMP DEPTH TBD BY CATCH BASIN SITE DESIGN ENGINEER OR MANHOLE (24" [600 mm] MIN RECOMMENDED) j � DC-780 CHAMBER 24" (600 mm) HDPE ACCESS PIPE REQUIRED USE FACTORY PRE -FABRICATED END CAP WITH FLAMP PART #: SC740EPE24BR DC-780 ISOLATOR ROW PLUS DETAIL NITS INSPECTION & MAINTENANCE STEP 1) INSPECT ISOLATOR ROW PLUS FOR SEDIMENT A. INSPECTION PORTS (IF PRESENT) A. 1. REMOVE/OPEN LID ON NYLOPLAST INLINE DRAIN A.2. REMOVE AND CLEAN FLEXSTORM FILTER IF INSTALLED A.3. USING A FLASHLIGHT AND STADIA ROD, MEASURE DEPTH OF SEDIMENT AND RECORD ON MAINTENANCE LOG A.4. LOWER A CAMERA INTO ISOLATOR ROW PLUS FOR VISUAL INSPECTION OF SEDIMENT LEVELS (OPTIONAL) A.5. IF SEDIMENT IS AT, OR ABOVE, 3" (80 mm) PROCEED TO STEP 2. IF NOT, PROCEED TO STEP 3. B. ALL ISOLATOR PLUS ROWS B. 1. REMOVE COVER FROM STRUCTURE AT UPSTREAM END OF ISOLATOR ROW PLUS B.2. USING A FLASHLIGHT, INSPECT DOWN THE ISOLATOR ROW PLUS THROUGH OUTLET PIPE i) MIRRORS ON POLES OR CAMERAS MAYBE USED TO AVOID A CONFINED SPACE ENTRY ii) FOLLOW OSHA REGULATIONS FOR CONFINED SPACE ENTRY IF ENTERING MANHOLE B.3. IF SEDIMENT IS AT, OR ABOVE, 3" (80 mm) PROCEED TO STEP 2. IF NOT, PROCEED TO STEP 3. STEP 2) CLEAN OUT ISOLATOR ROW PLUS USING THE JETVAC PROCESS A. A FIXED CULVERT CLEANING NOZZLE WITH REAR FACING SPREAD OF 45" (1.1 m) OR MORE IS PREFERRED B. APPLY MULTIPLE PASSES OF JETVAC UNTIL BACKFLUSH WATER IS CLEAN C. VACUUM STRUCTURE SUMP AS REQUIRED STEP 3) REPLACE ALL COVERS, GRATES, FILTERS, AND LIDS; RECORD OBSERVATIONS AND ACTIONS. STEP 4) INSPECT AND CLEAN BASINS AND MANHOLES UPSTREAM OF THE STORMTECH SYSTEM. AInTPQ 1. INSPECT EVERY 6 MONTHS DURING THE FIRST YEAR OF OPERATION. ADJUST THE INSPECTION INTERVAL BASED ON PREVIOUS OBSERVATIONS OF SEDIMENT ACCUMULATION AND HIGH WATER ELEVATIONS. 2. CONDUCT JETTING AND VACTORING ANNUALLY OR WHEN INSPECTION SHOWS THAT MAINTENANCE IS NECESSARY. CONCRETE COL PAVEMEN CONCRETE SLAB 6" (150 mm) MIN THICKNESS STORMTECH CHAMBER DC-780/SC-740 END CAP EOTEXTILE BETWEEN FOUNDATION STONE AND CHAMBERS 5' (1.5 m) MIN WIDE CONTINUOUS FABRIC WITHOUT SEAMS 12" (300 mm) MIN WIDTH r �NCRETE COLLAR NOT REQUIRED )R UNPAVED APPLICATIONS 8" NYLOPLAST INSPECTION PORT BODY (PART# 2708AG41PKIT) OR TRAFFIC RATED BOX W/SOLID LOCKING COVER 4" (100 mm) SDR 35 PIPE 4" (100 mm) INSERTA TEE TO BE CENTERED ON CORRUGATION CREST NOTE: INSPECTION PORTS MAY BE CONNECTED THROUGH ANY CHAMBER CORRUGATION CREST. 4" PVC INSPECTION PORT DETAIL U) Q J J r Lu Q Q N r 0 0 U) Z O Y U 00 J 0 2 N U 0 V O O r 0 N O Na O ow > N J O m M z� ¢_ 2 O w Q O J � J V2 SC SERIES CHAMBE NTS SHEET 1 of 1 OL.UASSIS N p E p SlcwmTech- �Z FOR STORMTECH �'` INSTRUCTIONS, DOWNLOAD THE INSTALLATION APP Le L' . StormTech Construction Guide REQUIRED MATERIALS AND EQUIPMENT LIST • Acceptable fill materials per Table 1 • ADS Plus and non -woven geotextile fabrics IMPORTANT NOTES: 46, , Stormffiech@ An utt�a company StormTech solid end caps and pre -cored end caps StormTech chambers StormTech manifolds and fittings A. This installation guide provides the minimum requirements for proper installation of chambers. Non -adherence to this guide may result in damage to chambers during installation. Replacement of damaged chambers during or after backfilling is costly and very time consuming. It is recommended that all installers are familiar with this guide, and that the contractor inspects the chambers for distortion, damage and joint integrity as work progresses. B. Use of a dozer to push embedment stone between the rows of chambers may cause damage to chambers and is not an acceptable backf ill method. Any chambers damaged by using the "dump and push" method are not covered under the StormTech standard warranty. C. Care should be taken in the handling of chambers and end caps. Avoid dropping, prying or excessive force on chambers during removal from pallet and initial placement. Requirement4 r System Installation, Excavate bed and prepare subgrade per engineer's plans. Place non -woven geotextile over prepared soils and up excavation walls. Install underdrains if required. Place clean, crushed, angular stone foundation 6" (150 mm) min. Compact to achieve a flat surface. Manifold, Scour Fabric and Chamber Assembly Install manifolds and lay out ADS PLUS fabric at inlet rows [min. 12.5 ft (3.8 m)] at each inlet end cap. Place a continuous piece along entire length of Isolator° PLUS Row(s). Attaching the End Caps Lift the end of the chamber a few inches off the ground. With the curved face of the end cap facing outward, place the end cap into the chamber's end corrugation. Align the first chamber and end cap of each row with inlet pipes. Contractor may choose to postpone stone placement around end chambers and leave ends of rows open for easy inspection of chambers during the backfill process. Prefabricated End Caps 24" (600 mm) inlets are the maximum size that can fit into a SC-740/DC-780 end cap and must be prefabricated with a 24" (600 mm) pipe stub. SC-310 chambers with a 12" (300 mm) inlet pipe must use a prefabricated end cap with a 12" (300 mm) pipe stub. When used on an Isolator Row PLUS, these end caps will contain a welded FLAMP (flared end ramp) that will lay on top of the ADS PLUS fabric (shown above) Continue installing chambers by overlapping chamber end corrugations. Chamber joints are labeled "Lower Joint — Overlap Here" and "Build this direction — Upper Joint" Be sure that the chamber placement does not exceed the reach of the construction equipment used to place the stone. Maintain minimum 6" (150 mm) spacing between rows. Isolator Row PLUS Place a continuous layer of ADS PLUS fabric between the foundation stone and the Isolator Row PLUS chambers, making sure the fabric lays flat and extends the entire width of the chamber feet. Drape a strip of ADS non -woven geotextile over the row of chambers (not required over DC-780). This is the same type of non -woven geotextile used as a separation layer around the angular stone of the StormTech system. 2 Initial Anchoring of Chambers - Embedment Stone Initial embedment shall be spotted along the centerline of the chamber evenly anchoring the lower portion of the chamber. This is best accomplished with a stone conveyor or excavator reaching along the row. Backfill of Chambers - Embedment Stone UNEVEN BACKFILL EVEN BACKFILL Backfill chambers evenly. Stone column height should never differ by more than 12" (300 mm) between adjacent chamber rows or between chamber rows and perimeter. No equipment shall be operated on the bed at this stage of the installation. Excavators must be located off the bed. Dump trucks shall not dump stone directly on to the bed. Dozers or loaders are not allowed on the bed at this time. PERIMETER NOT BACKFILLED PERIMETER FULLY BACKFILLED Perimeter stone must be brought up evenly with chamber rows. Perimeter must be fully backfilled, with stone extended horizontally to the excavation wall. Call StormTech at 888.892.2694 for technical and product information or visit www.stormtech.com 3 Backfill - Embedment Stone & Cover Stone Continue evenly back -filling between rows and around perimeter until embedment stone reaches tops of chambers. Perimeter stone must extend horizontally to the excavation wall for both straight or sloped sidewalls. Only after chambers have been backfilled to top of chamber and with a minimum 6" (150 mm) of cover stone on top of chambers can small dozers be used over the chambers for backfilling remaining cover stone. Inserta Tee Detail CONVEYANCE PIPE MATERIAL MAY VARY (PVC, HOPE, ETC.) L INSERTA TEE ­111 CONNECTION �� (X) PLACE ADS PLUS WOVEN GEOTEXTILE (CENTERED ON INSERTA-TEE INLET) OVER BEDDING STONE FOR SCOUR PROTECTION AT SIDE INLET CONNECTIONS, GEOTEXTILE MUST EXTEND 6" (150 mm) PAST CHAMBER FOOT NOTE: PART NUMBERS WILL VARY BASED ON INLET PIPE MATERIALS. CONTACT STORMTECH FOR MORE INFORMATION. Small dozers and skid loaders may be used to finish grading stone back -fill in accordance with ground pressure limits in Table 2. They must push material parallel to rows only. Never push perpendicular to rows. StormTech recommends that the contractor inspect chambers before placing final back -fill. Any chambers damaged by construction shall be removed and replaced. SECTION A -A DO NOT INSTALL INSERTA-TEE AT CHAMBERJOINTS A A INSERTA TEE TO BE INSTALLED, CENTERED OVER CORRUGATION SIDE VIEW CHAMBER MAX DIAMETER OF INSERTATEE HEIGHT FROM BASE OF CHAMBER(X) SC-310 6" (150 mm) 4" (100 mm) SC-740 10" (250 mm) 4" (100 mm) DC-780 10" (250 mm) 4" (100 mm) INSERTA TEE FITTINGS AVAILABLE FOR SDR 26, SDR 36, SCH 40 IPS GASKETED & SOLVENT W ELD, N-12, HP STORM, C-900 OR DUCTILE IRON. Final Backfill of Chambers — Fill Material Install non -woven geotextile over stone. Geotextile must overlap 24" (600 mm) min. where edges meet. Compact each lift of back -fill as specified in the site design engineer's drawings. Roller travel parallel with rows. StormTech Isolator Row PLUS Detail COVER ENTIRE ISOLATOR ROW PLUS WITH ADS GEOSYNTHETICS 601 T NON -WOVEN GEOTEXTILE SC-740 - 8' (2.4 m) MIN WIDE STRIP SC-310 - 5' (1.5 m) MIN WIDE STRIP CATCH BASIN OR MANHOLE i SUMP DEPTH BY SITE DESIGN ENGINEER NOTE: NON -WOVEN GEOTEXTILE OVER DC-780 CHAMBERS IS NOT REQUIRED. CHAMBER (SC-740 SHOWN) SC-740 & DC-780-24- (600 MM) HOPE ACCESS - ONE LAYER OF ADSPLUS125 WOVEN PIPE REQUIRED USE FACTORY GEOTEXTILE BETWEEN FOUNDATION STONE PREFABRICATED END CAP WITH FLAMP AND CHAMBERS PART #: SC740EPE24BR SC-740 & DC-780- 5(1.5 m) MIN WIDE STRIPS SC-310- 12"(300mm) HOPE ACCESS PIPE SC-310- 4'(12m) MIN WIDE STRIPS USE FACTORY PRE -FABRICATED END CAP CONTINUOUS FABRIC WITHOUT SEAMS PART#: SC310EPE12B 4 Table 1-Acceptable Fill Materials Material Location Description AASHTO M43 Compaction/Density Designation' Requirement (I)Final Fill: RII Material for layer'D' Any soil/rock materials, native soils WA Prepare per site design engineer's plans. Paved starts from the top of the'C' layer to the or per engineer's plans. Check installations may have stringent material and prepara- bottom of flexible pavement or unpaved plans for pavement subgrade tion requirements. finished grade above. Note that the pave- requirements. ment subbase may be part of the'D' layer. ©Initial Fill: RII Material for layer'C' Granular well -graded soil/ AASHTO M45 Begin compacton after min.12" (300 mm) of mate - starts from the top of the embedment aggregate mixtures, <35%fines A-1, A-2-4, A-3 rial over the chambers is reached. Compact additional stone ('B' layer) to 18" (450 mm) above or processed aggregate. Most or layers in 6" (150 mm) max. lifts to a min. 95% Proctor the top of the chamber. Note that pave- pavement subbase materials can AASHTO M431 density for well -graded material and 95% relative ment subbase may be part of the'C' layer be used in lieu of this layer. 3, 357, 4, 467, 5, 56, 57, 6, density for processed aggregate materials. Roller 67, 68, 7, 78, 8, 89, 9,10 gross vehicle weight not to exceed 12,000 Ibs (53 IkN). Dynamic force not to exceed 20,000 Ibs (89 kN) ®Embedment Stone: Embedment Clean, crushed, angular stone AASHTO M431 No compaction required. Stone surrounding chambers from the 3, 357, 4, 467, 5, 56, 57 foundation stone to the'C' layer above. (A)Foundation Stone: Foundation Stone Clean, crushed, angular stone, AASHTO M431 Place and compact in 6" (150 mm) lifts using two full below the chambers from the subgrade up 3, 357, 4, 467, 5, 56, 57 coverages with a vibratory compactorz3 to the foot (bottom) of the chamber. PLEASE NOTE: 1. The listed AASHTO designations are for gradations only. The stone must also be clean, crushed, angular. For example, a specification for #4 stone would state: "clean, crushed, angular no. 4 (AASHTO M43) stone 2. StormTech compaction requirements are met for A' location materials when placed and compacted in 6" (150 mm) (max) lifts using two full coverages with a vibratory compactor. 3. Where infiltration surfaces may be comprised by compaction, for standard installations and standard design load conditions, a flat surface may be achieved by raking or dragging without compaction equipment. For special load designs, contact Storm Tech for compaction requirements. Figure 2 - Fill Material Locations ADS GEOSYNTHETICS 601 T NON -WOVEN GEOTEXTILE ALL AROUND CLEAN, CRUSHED, ANGULAR STONE IN A& B LAYERS PERIMETER STONE EXCAVATION WALL (CAN BE SLOPED OR VERTICAL) 12" (300 Figure 1- Inspection Port Detail I CONCRETE COI PAVEMEN CONCRETE SLAB 6" (150 mm) MIN THICKNESS STORMTECH CHAMBER 12"(300 mm)MIN WIDTH CONCRETE COLLAR NOT REQUIRED 7R UNPAVED APPLICATIONS 8" NYLOPLAST INSPECTION PORT BODY (PART# 2708AG41PKIT) OR TRAFFIC RATED BOX W/SOLID LOCKING COVER 4" (100 mm) SDR 35 PIPE 4" (100 mm) INSERTA TEE TO BE CENTERED ON CORRUGATION CREST NOTE: INSPECTION PORTS MAY BE CONNECTED THROUGH ANY CHAMBER CORRUGATION CREST. PAVEMENT LAYER (DESIGNED BY SITE DESIGN ENGINEER) SC-740 & DC-780 -51" (1295 mm) SC-310 - 34' (865 mm) 8' 18" (2.4 m) (450 mm) MIN' MAX SC-740 & DC-780 - 30" (760 mm) SC-310 - 16" (406 mm) DEPTH OF STONE TO BE DETERMINED BY SITE DESIGN ENGINEER SC-740 & SC-310 - 6" (150 mm) MIN DC-780 - 9" (230 mm) MIN 5 NOTES. Table 2 - Maximum Allowable Construction Vehicle Loads5 1. 36" (900 mm) of stabilized cover materials over the chambers is required for full dump truck travel and dumping. 2. During paving operations, dump truck axle loads on 18" (450 mm) of cover maybe necessary. Precautions should be taken to avoid rutting of the road base layer, to ensure that compaction requirements have been met, and that a minimum of 18" (450 mm) of cover exists over the chambers. Contact StormTech for additional guidance on allowable axle loads during paving. 3. Ground pressure for track dozers is the vehicle operating weight divided by total ground contact area for both tracks. Excavators will exert higher ground pressures based on loaded bucket weight and boom extension. 4. Mini -excavators (< 8,000/bs/3,628 kg) can be used with at least 12" (300 mm) of stone over the chambers and are limited by the maximum ground pressures in Table 2 based on a full bucket at maximum boom extension. 5. Storage of materials such as construction materials, equipment, spoils, etc. should not be located over the StormTech system. The use of equipment over the StormTech system not covered in Table 2 (ex. soil mixing equipment, cranes, etc) is limited. Please contact StormTech for more information. 6. Allowable track loads based on vehicle travel only. Excavators shall not operate on chamber beds until the total backfill reaches 3 feet (900 mm) over the entire bed. ADS "Terms and Conditions of Sale" are available on the ADS website, www.ads-pipe.com. Advanced Drainage Systems, the ADS logo, and the green stripe are registered trademarks of Advanced Drainage Systems, Inc. StormTech® and the Isolator® Row PLUS are registered trademarks of Storm - Tech, Inc #11010 09/20 CS ©2020 Advanced Drainage Systems, Inc. Maximum Allowable Wheel Loads Maximum Allowable Track Loads' Maximum Allowable Roller Loads Fill Depth Material over Chambers Max Axle Load Max Wheel Load Track Max Ground Max Drum Weight Location in. [mm] for Trucks for Loaders lbs [kN] lbs [kN] in. [mm] lbs [kN] (Q) Final Fill 36" [900] 32,000 [142] 16,000 [71] psf[kPa] 12" [305] 20 [164] 38,000 [169] Material Compacted 18" [457] 0[113]30" F2350 V62]10 [72] 36" 9141063 ©Initial Fill 24" [600] 32,000 [142] 16,000 p1] 12" [305] 80 [119] 20,000 [89] Material Compacted 18" [457] 770 [85] 24" [610] 1430 [68] 30" V62] 1210 [58] 36" [914] 1070 [51 ] 24" [600] 32,000 [142] 16,000 [71] 12" [305] 2245 [107] 20,000 [89] Loose/Dumped 18" [457] 1625 [78] Roller gross vehicle weight not to 24" [610] 1325 [63] exceed 12,000 lbs. [53 kN] 30" V62] 1135 [54] 36" [914] 1010 [48] 18" [450] 32,000 [142] 16,000 [71] 12" [305] 2010 [96] 20,000 [89] 18" [457] 1480 [71 ] Roller gross vehicle weight not to 24" [610] 1220 [58] exceed 12,000 lbs. [53 kN] 30" V62] 1060 [51 ] 36" [914] 950 [45] ©Embedment 12" [300] 16,000 [71] NOTALLOWED 12" [305] 1540 [74] 20,000 [89] Stone 18" [457] 1190 [57] Roller gross vehicle weight not to 24" [610] 1010 [48] exceed 12,000 lbs. [53 kN] 30" V62] 910 [43] 36" [9141 840 40 6" [150] 8,000 [35] NOTALLOWED 12" [305] 1070 [51] NOT ALLOWED 18" [457] 900 [43] 24" [610] 800 [38] 30" V62] 760 [36] 36" [9141 1 720 34 Table 3 - Placement Methods and Descriptions (R) Final Fill A variety of placement methods may be 36" (900 mm) minimum Dozers to push parallel to Roller travel parallel to rows Material used. Al construction loads must not cover required for dump rows until 36" (900mm) only until 36" (900 mm) exceed the maximum limits in Table 2. trucks to dump over compaced cover is compacted cover is chambers. reached.' reached. © Initial Fill Excavator positioned off bed recommended. Asphalt can be dumped into Small LGP track dozers & skid Use dynamic force of roller Material Small excavator allowed over paver when compacted loaders allowed to grade cover only after compacted fill chambers. Small dozer allowed. pavement subbase reaches stone with at least 6" (150 mm) depth reaches 12" (300 mm) 18" (450 mm) above top of stone under tracks at all times. over chambers. Roller travel chambers. Equipment must push parallel parallel to chamber rows only. to rows at all times. ®Embedment No equipment allowed on bare chambers. No wheel loads allowed. No tracked equipment is No rollers allowed. Stone Use excavator or stone conveyor Material must be placed allowed on chambers until a positioned off bed or on foundation outside the limits of the min. 6" (150 mm) cover stone to evenly fill around all chambers chamber bed. stone is in place. to at least the top of chambers. QFoundation No StormTech restrictions. Contractor responsible for any conditions or requirements by others relative to subgrade bearing Stone capacity, dewatering or protection of subgrade. Call StormTech at 888.892.2694 for technical and product information or visit www.stormtech.com 17.0 Standard Limited Warranty StormTech® STANDARD LIMITED WARRANTY OF STORMTECH LLC ("STORMTECH"): PRODUCTS (A) This Limited Warranty applies solely to the StormTech (F) chambers and end plates manufactured by StormTech and sold to the original purchaser (the "Purchaser"). The chambers and end plates are collectively referred to as the "Products." (B) The structural integrity of the Products, when installed strictly in accordance with StormTech's written installation instructions at the time of installation, are warranted to the Purchaser against defective materials and workmanship for one (1) year from the date of purchase. Should a defect appear in the Limited Warranty period, the Purchaser shall provide StormTech with written notice of the alleged defect at StormTech's corporate headquarters within ten (10) days of the discovery of the defect. The notice shall describe the alleged defect in reasonable detail. StormTech agrees to supply replacements for those Products determined by StormTech to be defective and covered by this Limited Warranty. The supply of replacement products is the sole remedy of the Purchaser for breaches of this Limited Warranty. StormTech's liability specifically excludes the cost of removal and/or installation of the Products. (C) THIS LIMITED WARRANTY IS EXCLUSIVE. THERE ARE NO OTHER WARRANTIES WITH RESPECT TO THE PRODUCTS, INCLUDING NO IMPLIED WARRANTIES OF MERCHANTABILITY OR OF FITNESS FOR A PARTICULAR PURPOSE. (D) This Limited Warranty only applies to the Products when the Products are installed in a single layer. UNDER NO CIRCUMSTANCES, SHALL THE PRODUCTS BE INSTALLED IN A MULTI -LAYER CONFIGURATION. (E) No representative of StormTech has the authority to change this Limited Warranty in any manner or to extend this Limited Warranty. This Limited Warranty does not apply to any person other than to the Purchaser. Under no circumstances shall StormTech be liable to the Purchaser or to any third party for product liability claims; claims arising from the design, shipment, or installation of the Products, or the cost of other goods or services related to the purchase and installation of the Products. For this Limited Warranty to apply, the Products must be installed in accordance with all site conditions required by state and local codes; all other applicable laws; and StormTech's written installation instructions. (G) THE LIMITED WARRANTY DOES NOT EXTEND TO INCIDENTAL, CONSEQUENTIAL, SPECIAL OR INDIRECT DAMAGES. STORMTECH SHALL NOT BE LIABLE FOR PENALTIES OR LIQUIDATED DAMAGES, INCLUDING LOSS OF PRODUCTION AND PROFITS; LABOR AND MATERIALS; OVERHEAD COSTS; OR OTHER LOSS OR EXPENSE INCURRED BY THE PURCHASER OR ANY THIRD PARTY. SPECIFICALLY EXCLUDED FROM LIMITED WARRANTY COVERAGE ARE DAMAGE TO THE PRODUCTS ARISING FROM ORDINARY WEAR AND TEAR; ALTERATION, ACCIDENT, MISUSE, ABUSE OR NEGLECT, THE PRODUCTS BEING SUBJECTED TO VEHICLE TRAFFIC OR OTHER CONDITIONS WHICH ARE NOT PERMITTED BY STORMTECH'S WRITTEN SPECIFICATIONS OR INSTALLATION INSTRUCTIONS; FAILURE TO MAINTAIN THE MINIMUM GROUND COVERS SET FORTH IN THE INSTALLATION INSTRUCTIONS; THE PLACEMENT OF IMPROPER MATERIALS INTO THE PRODUCTS; FAILURE OF THE PRODUCTS DUE TO IMPROPER SITING OR IMPROPER SIZING; OR ANY OTHER EVENT NOT CAUSED BY STORMTECH. A PRODUCT ALSO IS EXCLUDED FROM LIMITED WARRANTY COVERAGE IF SUCH PRODUCT IS USED IN A PROJECT OR SYSTEM IN WHICH ANY GEOTEXTILE PRODUCTS OTHER THAN THOSE PROVIDED BY ADVANCED DRAINAGE SYSTEMS ARE USED. THIS LIMITED WARRANTY REPRESENTS STORMTECH'S SOLE LIABILITY TO THE PURCHASER FOR CLAIMS RELATED TO THE PRODUCTS, WHETHER THE CLAIM IS BASED UPON CONTRACT, TORT, OR OTHER LEGAL THEORY. 41 StormTech® Detention • Retention . Water Quality An company 20 Beaver Road, Suite 104 I Wethersfield I Connecticut 106109 888.892.2694 fax 866.328.8401 www.stormtech.com 1111111 m9m, GEOSYNTHEl'ICS ADS GEOSYNTHETICS 0601T NONWOVEN GEOTEXTILE Scope This specification describes ADS Geosynthetics 6.0 oz (0601T) nonwoven geotextile. Filter Fabric Requirements ADS Geosynthetics 6.0 oz (0601T) is a needle -punched nonwoven geotextile made of 100% polypropylene staple fibers, which are formed into a random network for dimensional stability. ADS Geosynthetics 6.0 oz (0601T) resists ultraviolet deterioration, rotting, biological degradation, naturally encountered basics and acids. Polypropylene is stable within a pH range of 2 to 13. ADS Geosynthetics 6.0 oz (0601T) conforms to the physical property values listed below: Filter Fabric Properties PROPERTY TEST METHOD UNIT M.A.R.V. (Minimum Average Roll Value) Weight (Typical) ASTM D 5261 oz/yd2 (g/m2) 6.0(203) Grab Tensile ASTM D 4632 Ibs (kN) 160 (0.711) Grab Elongation ASTM D 4632 % 50 Trapezoid Tear Strength ASTM D 4533 Ibs (kN) 60 (0.267) CBR Puncture Resistance ASTM D 6241 Ibs (kN) 410 (1.82) Permittivity* ASTM D 4491 sec' 1.5 Water Flow* ASTM D 4491 gpm/ft2 (Vmin/m2) 110 (4480) AOS* ASTM D 4751 US Sieve (mm) 70 (0.212) UV Resistance ASTM D 4355 %/hrs 70/500 PACKAGING Roll Dimensions (W x L) — ft 12.5 x 360 / 15 x 300 Square Yards Per Roll 500 Estimated Roll Weight — Ibs 195 " At the time of manufacturing. Handling may change these properties. ADS "Terms and Conditions of Sale" can be found on the ADS webs ite, www.ads-pipe.com Advanced Drainage Systems and the ADS logo is a registered trademark of Advanced Drainage Systems, Inc. ©Advanced Drainage Systems, Inc. #0601T 02/12 1111111 m9m, GEOSYNTHEl'ICS ADS GEOSYNTHETICS 315W WOVEN GEOTEXTILE Scope This specification describes ADS Geosynthetics 315W woven geotextile. Filter Fabric Requirements ADS Geosynthetics 315W is manufactured using high tenacity polypropylene yarns that are woven to form a dimensionally stable network, which allows the yarns to maintain their relative position. ADS Geosynthetics 315W resists ultraviolet deterioration, rotting and biological degradation and is inert to commonly encountered soil chemicals. ADS Geosynthetics 315W conforms to the physical property values listed below: Filter Fabric Properties PROPERTY TEST METHOD ENGLISH M.A.R.V. (Minimum Average Roll Value) METRIC M.A.R.V. (Minimum Average Roll Value) Tensile Strength (Grab) ASTM D-4632 315 Ibs 1400 N Elongation ASTM D-4632 15% 15% CBR Puncture ASTM D-6241 900 Ibs 4005 N Puncture ASTM D-4833 150 Ibs 667 N Mullen Burst ASTM D-3786 600 psi 4134 kPa Trapezoidal Tear ASTM D-4533 120 Ibs 533 N UV Resistance (at 500 hrs) ASTM D-4355 70% 70% Apparent Opening Size (AOS)* ASTM D-4751 40 US Std. Sieve 0.425 mm Permittivity ASTM D-4491 .05 sec' .05 sec' Water Flow Rate ASTM D-4491 4 gpm/ft2 163 I/min/m2 Roll Sizes 12.5'x360' 15.0' x 300' 17.5'x258' 3.81 mx109.8m 4.57 m x 91.5 m 5.33mx78.6m "Maximum average roll value. ADS "Terms and Conditions of Sale" can be found on the ADS website, www.ads-pipe.com Advanced Drainage Systems and the ADS logo is a registered trademark of Advanced Drainage Systems, Inc. ©Advanced Drainage Systems, Inc. #315W 02/12 StormTech' MlC11111111111111111113500 -namb�. Designed to meet the most stringent industry performance standards for superior structural integrity while providing designers with a cost-effective method to save valuable land and protect water resources. The StormTech system is designed primarily to be used under parking lots, thus maximizing land usage for private (commercial) and public applications. StormTech -nbers can also be used in conjunction with Green Infrastructure, thus enhancing the performance and extending the service life of these practices. Nominal Chamber Specifications (not to scale) Size (L x W x H) 90" x 77" x 45" 2286 mm x 1956 mm x 1143 mm Chamber Storage 109.9 ft3 (3.11 m3) Min. Installed Storage* 175.0 ft3 (4.96 m3) Weight 134 Ibs (60.8 kg) Shipping 15 chambers/pallet 7 end caps/pallet 7 pallets/truck *Assumes a minimum of 12" (300 mm) of stone above, 9" (230 mm) of stone below chambers, 6" (150 mm) of stone between chambers/ end caps and 40% stone porosity. EMBEDMENT STONE SHALL BE A CLEAN, CRUSHED AND AN GUTAR STONE WITH AN AASHTOM43DESIGNATION BETWEEN# AND# CHAMBERSSHALLMEETASTM F2418"STANDARD SPECIFICATION FOR POLVPROPLENE (PP) CORRUGATED WALL STORM WATER COLLECTION CHAMBERS' ADS GEOSVTHETIGS 601T NONWOVEN GEOTEXTILE ALL AROUND CLEAN, CRUSHED, ANGUTAREMBEDMENTSTONE Nominal End Cap Specifications (not to scale) Size (L x W x H) 26.5"x71"x45.1" 673 mm x 1803 mm x 1145 mm End Cap Storage 14.9 ft3 (0.42 m3) Min. Installed Storage* 45.1 ft3 (1.28 m3) Weight 49 Ibs (22.2 kg) 22.5" (571 mn) INSTALLED 45A" (1143 mm) 25.7" (653 nn) (1956 mm) 45.0" (1143 mm) 77.0" �- I^ (1956 nm) -I *Assumes a minimum of 12" (300 mm) of stone above, 9" (230 mm) of stone below, 6" (150 mm) of stone perimeter, 6" (156 mm) of stone between chambers/ end caps and 40% stone porosity. GRANULARWELL-GRADEDSOILIAGGREGATEMIXTURES,< % FINES, COM PACT IN I2" (300 mm) MAX LIFTS TO %% PROCTOR i DENSITY. SEETHE TABLE OF ACCEPTABLE FILL MATERIALS. CHAMBERS SHALL BE BE DESIGNED IN ACCORDANCE WITH ASTM F2 "STANDARD PRACTICE FORSTRUCTURAL DESIGN OFTHERMOPLASTIC CORRUGATED WALL STORM WATER COLLECTION CHAMBERS". PAVEMENT LAYER(DESIGNED /'' r BV SITEOESIGNENGINEER) \ / , 1 e PERIMETERSTONE (450mm)MIN' (24m) MAX 12" (300 mm)MIN EXGAVATION WALL (CAN BESLQPEB- ORVERTIGIL) f� II„ I I -T- T' L DEPTH OFSTONETOBEOETERMINI (150mm)MIN IIIII II IIII"I l�Ev BV SITE DESIGN ENGINEERO'-I MC GAP III III / 6' ]] 1950 mm 12" 300 mm TYP 150 mm MIN I ( ) _( ) ENO GIP ( ) Ir SITE DESIGN ENGINEER IS RESPONSIBLE FOR ENSURING _ THE REQUIRED BEARING GIPACITY OF SOILS 'MINIMUM COVER TO BOTTOM OF FLEXIBLE PAVEM ENT. FOR UNPAVED INSTALLATIONS WHERE RUTTING FROM VEHICLES MAY OCCUR, INCREASE GMER T024" (600 mm). ///" StormTech 'v StormTech MC-3500 Specifications Storage Volume Per Chamber Chamber 109.9 (3.11) 175.0 (4.96) 179.9 (5.09) 184.9 (5.24) 189.9 (5.38) End Cap 14.9 (0.42) 45.1 (1.28) 46.6 (1.32) 48.3 (1.37) 49.9 (1.41) Note: Assumes 6" (150 mm) row spacing, 40% stone porosity, 12" (300 mm) stone above and includes the bare chamber/end cap volume. Amount of Stone Per Chamber Stone FoundationINV Depth Chamber 8.5 (6.0) 9.1 (6.5) 9.7 (6.9) 10.4 (7.4) End Cap 3.9 (2.8) 4.1 (2.9) 4.3 (3.1) 4.5 (3.2) KilogramsMetric M I� Chamber 7711 (4.6) 8255 (5.0) 8800 (5.3) 9435 (5.7) End Cap 3538 (2.1) 3719 (2.2) 3901 (2.4) 4082 (2.5) Note: Assumes 12" (300 mm) of stone above and 6" (150 mm) row spacing and 6" (150 mm) of perimeter stone in front of end caps. Volume Excavation Per Chamber yd3 (m3) Chamber 11.9 (9.1) 12.4 (9.5) 12.8 (9.8) 13.3 (10.2) End Cap 4.0 (3.1) 4.1 (3.3) 4.3 (3.3) 4.4 (3.4) Note: Assumes 6" (150 mm) of separation between chamber rows and 24" (600 mm) of cover. The volume of excavation will vary as depth of cover increases. Working on a project? Visit us at ✓ww.stormtech.cor and utilize the Design Tool AAWStormTech, 4w adspipe.com 800-821-6710 ADS "Terms and Conditions of Sale" are available on the ADS webslte, www.aos-pipe.com The ADS logo and the Green Stripe are registered trademarks of Advanced Drainage Systems, Inc. StormTech- is a registered trademark of StormTech, Inc. © 2022 Advanced Drainage Systems, Inc. #S7509091/22 CS ACCEPTABLE FILL MATERIALS: STORMTECH MC-3500 CHAMBER SYSTEMS AASHTO MATERIAL MATERIAL LOCATION DESCRIPTION COMPACTION / DENSITY REQUIREMENT CLASSIFICATIONS FINAL FILL: FILL MATERIAL FOR LAYER'D' STARTS FROM THE PREPARE PER SITE DESIGN ENGINEER'S PLANS. PAVED D TOP OF THE'C' LAYER TO THE BOTTOM OF FLEXIBLE ANY SOIL/ROCK MATERIALS, NATIVE SOILS, OR PER ENGINEER'S PLANS. N/A INSTALLATIONS MAY HAVE STRINGENT MATERIAL AND PAVEMENT OR UNPAVED FINISHED GRADE ABOVE. NOTE THAT CHECK PLANS FOR PAVEMENT SUBGRADE REQUIREMENTS. PREPARATION REQUIREMENTS. PAVEMENT SUBBASE MAY BE PART OF THE'D' LAYER AASHTO M145' INITIAL FILL: FILL MATERIAL FOR LAYER'C' STARTS FROM THE GRANULAR WELL -GRADED SOIL/AGGREGATE MIXTURES, <35% FINES OR A-1, A-2-4, A-3 BEGIN COMPACTIONS AFTER 24" (600 mm) OF MATERIAL OVER TOP OF THE EMBEDMENT STONE ('B' LAYER) TO 24" (600 mm) PROCESSED AGGREGATE. THE CHAMBERS IS REACHED. COMPACT ADDITIONAL LAYERS IN C ABOVE THE TOP OF THE CHAMBER. NOTE THAT PAVEMENT OR 12" (300 mm) MAX LIFTS TO A MIN. 95% PROCTOR DENSITY FOR SUBBASE MAY BE A PART OF THE'C' LAYER. MOST PAVEMENT SUBBASE MATERIALS CAN BE USED IN LIEU OF THIS WELL GRADED MATERIAL AND 95% RELATIVE DENSITY FOR LAYER. AASHTO M43 PROCESSED AGGREGATE MATERIALS. 3, 357, 4, 467, 5, 56, 57, 6, 67, 68, 7, 78, 8, 89, 9, 10 EMBEDMENT STONE: FILL SURROUNDING THE CHAMBERS AASHTO M43' B FROM THE FOUNDATION STONE ('A' LAYER) TO THE'C' LAYER CLEAN, CRUSHED, ANGULAR STONE 3,4 NO COMPACTION REQUIRED. ABOVE. A FOUNDATION STONE: FILL BELOW CHAMBERS FROM THE CLEAN, CRUSHED, ANGULAR STONE AASHTO M43' PLATE COMPACT OR ROLL TO ACHIEVE A FLAT SURFACE23 SUBGRADE UP TO THE FOOT (BOTTOM) OF THE CHAMBER. 3,4 PLEASE NOTE: 1. THE LISTED AASHTO DESIGNATIONS ARE FOR GRADATIONS ONLY. THE STONE MUST ALSO BE CLEAN, CRUSHED, ANGULAR. FOR EXAMPLE, A SPECIFICATION FOR #4 STONE WOULD STATE: "CLEAN, CRUSHED, ANGULAR NO. 4 (AASHTO M43) STONE". 2. STORMTECH COMPACTION REQUIREMENTS ARE MET FORA' LOCATION MATERIALS WHEN PLACED AND COMPACTED IN 9" (230 mm) (MAX) LIFTS USING TWO FULL COVERAGES WITH A VIBRATORY COMPACTOR. 3. WHERE INFILTRATION SURFACES MAY BE COMPROMISED BY COMPACTION, FOR STANDARD DESIGN LOAD CONDITIONS, A FLAT SURFACE MAY BE ACHIEVED BY RAKING OR DRAGGING WITHOUT COMPACTION EQUIPMENT. FOR SPECIAL LOAD DESIGNS, CONTACT STORMTECH FOR COMPACTION REQUIREMENTS. 4. ONCE LAYER'C' IS PLACED. ANY SOIL/MATERIAL CAN BE PLACED IN LAYER'D' UP TO THE FINISHED GRADE. MOST PAVEMENT SUBBASE SOILS CAN BE USED TO REPLACE THE MATERIAL REQUIREMENTS OF LAYER 'C' OR'D' AT THE SITE DESIGN ENGINEER'S DISCRETION. PERIMETER STONE (SEE NOTE 4) EXCAVATION WALL (CAN BE SLOPED OR VERTICAL; 6" (15C ADS GEOSYNTHETICS 601T NON -WOVEN GEOTEXTILE ALL AROUND CLEAN, CRUSHED, ANGULAR STONE IN A & B LAYERS M C-3500 END CAP SUBGRADE SOILS (SEE NOTE 3) 1 LAYER OF ADS GEOSYNTHETICS NON -WOVEN GEOTEXTILE BEWTEEN COVER STONE AND C LAYER. O "TO BOTTOM OF FLEXIBLE PAVEMENT. FOR UNPAVED NSTALLATIONS WHERE RUTTING FROM VEHICLES MAY OCCUR,\ INCREASE COVER TO 30"(750mm). '11- 1 8' 18" (450 mm) (2.4 m) MIN" MAX 12" (300 mm) MIN 45" (1143 mm) DEPTH OF STONE TO BE DETERMINED BY SITE DESIGN ENGINEER 9" (230 mm) MIN -III 61IIIIIIL -III=III 77" (1956 mm) 12" (300 mm) MIN (150 mm) MIN *FOR COVER DEPTHS GREATER THAN 8.0' (2.4 m) PLEASE CONTACT STORMTECH NOTES: 1. CHAMBERS SHALL MEET THE REQUIREMENTS OF ASTM F2418-16a, "STANDARD SPECIFICATION FOR POLYPROPYLENE (PP) CORRUGATED WALL STORMWATER COLLECTION CHAMBERS" CHAMBER CLASSIFICATION 45x76 DESIGNATION SS. 2. MC-3500 CHAMBERS SHALL BE DESIGNED IN ACCORDANCE WITH ASTM F2787 "STANDARD PRACTICE FOR STRUCTURAL DESIGN OF THERMOPLASTIC CORRUGATED WALL STORMWATER COLLECTION CHAMBERS". 3. THE SITE DESIGN ENGINEER IS RESPONSIBLE FOR ASSESSING THE BEARING RESISTANCE (ALLOWABLE BEARING CAPACITY) OF THE SUBGRADE SOILS AND THE DEPTH OF FOUNDATION STONE WITH CONSIDERATION FOR THE RANGE OF EXPECTED SOIL MOISTURE CONDITIONS. 4. PERIMETER STONE MUST BE EXTENDED HORIZONTALLY TO THE EXCAVATION WALL FOR BOTH VERTICAL AND SLOPED EXCAVATION WALLS. 5. REQUIREMENTS FOR HANDLING AND INSTALLATION: • TO MAINTAIN THE WIDTH OF CHAMBERS DURING SHIPPING AND HANDLING, CHAMBERS SHALL HAVE INTEGRAL, INTERLOCKING STACKING LUGS. • TO ENSURE A SECURE JOINT DURING INSTALLATION AND BACKFILL, THE HEIGHT OF THE CHAMBER JOINT SHALL NOT BE LESS THAN 3". • TO ENSURE THE INTEGRITY OF THE ARCH SHAPE DURING INSTALLATION, a) THE ARCH STIFFNESS CONSTANT AS DEFINED IN SECTION 6.2.8 OF ASTM F2418 SHALL BE GREATER THAN OR EQUAL TO 500 LBS/IN/IN. AND b) TO RESIST CHAMBER DEFORMATION DURING INSTALLATION AT ELEVATED TEMPERATURES (ABOVE 73° F / 23° C), CHAMBERS SHALL BE PRODUCED FROM REFLECTIVE GOLD OR YELLOW COLORS. 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Ln I� co O Ln Ih O O O N N E E E E E E E "0 co O P-m V 0') CD M co W co M N io - O Co M M M Cl) o 00 V ri Cl) co ai N (o N Cl) N Co N m E E E E E E E E M O O O Ln O O Ln Ih Co Ln O O O Ln VJ O LD 0 cli U') W N CD � CO LL CO LL m LL W LL O a O a N N a N a Ln a Ln a F a F m a m M H a H m a M m m a LL w LL w LL w LL w LL w LL w LL w LL w LL w LL w W a W w a w W a W w a w w a00000s0s0s o m O U')m o O U')m o O U')m o 0 Ln 0 Ln 0 Ln o CD s CDCo o 0 0 o 0 s 0 o 0 0 0 0 0 a M M M M M M M M M M M M M M M M M M M g g g g g g g g g g g g g g g g g g g COVER PIPE CONNECTION TO END INSTALL FLAMP ON 24" (600 mm) ACCESS PIPE OPTIONAL INSPECTION PORT CAP WITH ADS GEOSYNTHETICS 601T PART #: MC350024RAMP Q NON -WOVEN GEOTEXTILE Lu MC-3500 CHAMBER 0 p o MC-3500 END CAP z Y O 0 C) J w _ _ Ln p U z 0 M STORMTECH HIGHLY RECOMMENDS 0 r FLEXSTORM INSERTS IN ANY UPSTREAM ��0,����0,���°,����0,����0,����0,����0,����0,����0,����0,����0,���0,����0,����0,���1���0,����0,����0,����0,����0,����0,����0,����0,����0,����0,� ����0,����0,����0,����0,����0,����0,����0,����0 ��0,����0,����0,����0,����0,����0,���°,����0,����;Lr N O STRUCTURES WITH OPEN GRATES N a 00 0 z ELEVATED BYPASS MANIFOLD J w a _ w P O - Q 0- w SUMP DEPTH TBD BY CATCH BASIN SITE DESIGN ENGINEER OR MANHOLE (24" [600 mm] MIN RECOMMENDED) j � 24" (600 mm) HDPE ACCESS PIPE REQUIRED USE FACTORY PARTIAL CUT END CAP PART #: MC35001EPP24BC OR MC35001EPP24BW MC-3500 ISOLATOR ROW PLUS DETAIL NITS INSPECTION & MAINTENANCE STEP 1) INSPECT ISOLATOR ROW PLUS FOR SEDIMENT A. INSPECTION PORTS (IF PRESENT) A.1. REMOVE/OPEN LID ON NYLOPLAST INLINE DRAIN A.2. REMOVE AND CLEAN FLEXSTORM FILTER IF INSTALLED CONCRETE C A.3. USING A FLASHLIGHT AND STADIA ROD, MEASURE DEPTH OF SEDIMENT AND RECORD ON MAINTENANCE LOG PAVEM A.4. LOWER A CAMERA INTO ISOLATOR ROW PLUS FOR VISUAL INSPECTION OF SEDIMENT LEVELS (OPTIONAL) A.5. IF SEDIMENT IS AT, OR ABOVE, 3" (80 mm) PROCEED TO STEP 2. IF NOT, PROCEED TO STEP 3. B. ALL ISOLATOR PLUS ROWS B.1. REMOVE COVER FROM STRUCTURE AT UPSTREAM END OF ISOLATOR ROW PLUS B.2. USING A FLASHLIGHT, INSPECT DOWN THE ISOLATOR ROW PLUS THROUGH OUTLET PIPE CONCRETE SLAB i) MIRRORS ON POLES OR CAMERAS MAYBE USED TO AVOID A CONFINED SPACE ENTRY 6" (150 mm) MIN THICKNE ii) FOLLOW OSHA REGULATIONS FOR CONFINED SPACE ENTRY IF ENTERING MANHOLE B.3. IF SEDIMENT IS AT, OR ABOVE, 3" (80 mm) PROCEED TO STEP 2. IF NOT, PROCEED TO STEP 3. STEP 2) CLEAN OUT ISOLATOR ROW PLUS USING THE JETVAC PROCESS STORMTECH CHAMBER A. A FIXED CULVERT CLEANING NOZZLE WITH REAR FACING SPREAD OF 45" (1.1 m) OR MORE IS PREFERRED B. APPLY MULTIPLE PASSES OF JETVAC UNTIL BACKFLUSH WATER IS CLEAN C. VACUUM STRUCTURE SUMP AS REQUIRED STEP 3) REPLACE ALL COVERS, GRATES, FILTERS, AND LIDS; RECORD OBSERVATIONS AND ACTIONS. STEP 4) INSPECT AND CLEAN BASINS AND MANHOLES UPSTREAM OF THE STORMTECH SYSTEM. N[)TF4 1. INSPECT EVERY 6 MONTHS DURING THE FIRST YEAR OF OPERATION. ADJUST THE INSPECTION INTERVAL BASED ON PREVIOUS OBSERVATIONS OF SEDIMENT ACCUMULATION AND HIGH WATER ELEVATIONS. 2. CONDUCT JETTING AND VACTORING ANNUALLY OR WHEN INSPECTION SHOWS THAT MAINTENANCE IS NECESSARY. ONE LAYER OF ADSPLUS175 WOVEN GEOTEXTILE BETWEEN FOUNDATION STONE AND CHAMBERS 8.25' (2.51 m) MIN WIDE CONTINUOUS FABRIC WITHOUT SEAMS 12" (300 mm) MIN WIDTH r �NCRETE COLLAR NOT REQUIRED )R UNPAVED APPLICATIONS 8" NYLOPLAST INSPECTION PORT BODY (PART# 2708AG41PKIT) OR TRAFFIC RATED BOX W/SOLID LOCKING COVER 4" (100 mm) SDR 35 PIPE 4" (100 mm) INSERTA TEE TO BE CENTERED ON CORRUGATION VALLEY NOTE: INSPECTION PORTS MAY BE CONNECTED THROUGH ANY CHAMBER CORRUGATION VALLEY. 4" PVC INSPECTION PORT DETAIL O MC SERIES CHAMBE NTS SHEET 1 of 1 ADS® StormTech® Installation Guide mr -`00 & MC-4500 Chamber Required Materials and Equipment List • Acceptable fill materials per Table 1 • StormTech solid end caps, pre -cored and pre -fabricated end caps • ADS Plus and non -woven geotextile fabrics • StormTech chambers, manifolds and fittings StormTech Installation Video Note: MC-3500 chamber pallets are 77" x 90" (2.0 m x 2.3 m) and weigh about 2010 lbs. (912 kg) and MC-4500 pallets are 100"x 52" (2.5 m x 1.3 m) and weigh about 840 lbs. (381 kg). Unloading chambers requires 72" (1.8 m) (min.) forks and/or tie downs (straps, chains, etc). Important Notes: A. This installation guide provides the minimum requirements for proper installation of chambers. Nonadherence to this guide may result in damage to chambers during installation. Replacement of damaged chambers during or after backfilling is costly and very time consuming. It is recommended that all installers are familiar with this guide, and that the contractor inspects the chambers for distortion, damage and joint integrity as work progresses. B. Use of a dozer to push embedment stone between the rows of chambers may cause damage to chambers and is not an acceptable backfill method. Any chambers damaged by using the "dump and push" method are not covered under the StormTech standard warranty. C. Care should be taken in the handling of chambers and end caps. End caps must be stored standing upright. Avoid dropping, prying or excessive force on chambers during removal from pallet and initial placement. Requirei , ,ants. Syste, istallatioi Excavate bed and prepare subgrade per engineer's plans. Plans and specifications should include Best Management Practices (BMPs) to deter contamination of open pits during construction. Place non -woven geotextile over prepared soils and up excavation walls. Place clean, crushed, angular stone foundation 9" (230 mm) min. Install underdrains if required. Compact to achieve a flat surface. Manifold, Scour Fabric and Chamber Assembly Install manifolds and layout ADS PLUS fabric at inlet rows [min. 17.5 ft (5.33 m)] at each inlet end cap. Place a continuous piece (no seams) along entire length of Isolator° PLUS Row(s). Align the first chamber and end cap of each row with inlet pipes. Contractor may choose to postpone stone placement around end chambers and leave ends of rows open for easy inspection of chambers during the backfill process. Manifold Insertion 12" (300 mm) MIN INSERTION STORMTECH END CAP MANIFOLD STUB MANIFOLD TRUNK 12" (300 mm) MIN SEPARATION NOTE: MANIFOLD STUB MUST BE LAID HORIZONTAL FOR A PROPER FIT IN END CAP OPENING. Insert inlet and outlet manifolds a minimum 12" (300 mm) into chamber end caps. Manifold header should be a minimum 12" (300 mm) from base of end cap. Continue installing chambers by overlapping chamber end corrugations. Chamberjoints are labeled "Lower joint - Overlap Here" and "Build this direction - Upper Joint" Be sure that the chamber placement does not exceed the reach of the construction equipment used to place the stone. Maintain minimum 6" (150 mm) spacing between MC-3500 rows and 9" (230 mm) spacing between MC-4500 rows. COVER PIPE CONNECTION TO END CAP WITH ADS GEOSYNTHETICS 601T NONWOVENGEOTEXTILE STORMTECH HIGHLY RECOMMENDS FLEXSTORM INSERTS IN ANY UPSTREAM STRUCTURES WITH OPEN GRATES ELEVATED BYPASS MANIFOLD SUMP BE PTH THE BY CATCH BASIN SITE DES I ON ENGI NEER OR MANHOLE (24' 1600 mm] MIN RECOMMENDED) Place a continuous layer of ADS PLUS fabric between the foundation stone and the Isolator Row PLUS chambers, making sure the fabric lays flat and extends the entire width of the chamber feet. When used on an Isolator Row PLUS, a 24" FLAMP (flared end ramp) is attached to the inside of the inlet pipe with a provided threaded rod and bolt. The FLAMP then lays on top of the ADS PLUS fabric. INSTALL FLAMP ON 24' (600 mm) ACCESS PIPE OPTIONAL INSPECTION PORT r CHAMBER (MCd5005HOWN) a� r END CAP (MC 4500 SHOWN) 24' (600 mm) HOPE ACCESS PIPE REQUIRED / / ONE LAYER OF ADSPLUS175 WOVEN GEOTEXTILE BETWEEN FOUNDATION STONE AND CHAMBERS 2 Initial Anchoring of Chambers - Embedment Stone Initial embedment shall be spotted along the centerline of the chamber evenly anchoring the lower portion of the chamber. This is best accomplished with a stone conveyor or excavator reaching along the row Backfill of Chambers - Embedment Stone Uneven Backfill Even Backfill Backfill chambers evenly. Stone column height should never differ by more than 12" (300 mm) between adjacent chamber rows or between chamber rows and perimeter. ///"StormTech No equipment shall be operated on the bed at this stage of the installation. Excavators must be located off the bed. Dump trucks shall not dump stone directly on to the bed. Dozers or loaders are not allowed on the bed at this time. Perimeter Not Backfilled Perimeter Fully Backfilled Perimeter stone must be brought up evenly with chamber rows. Perimeter must be fully back -filled, with stone extended horizontally to the excavation wall. 3 Backfill of Chambers - Embedment Stone and Cover Stone Continue evenly backfilling between rows and around perimeter until embedment stone reaches tops of chambers and a minimum 12" (300 mm) of cover stone is in place. Perimeter stone must extend horizontally to the excavation wall for both straight or sloped sidewalls. The recommended backfill methods are with a stone conveyor outside of the bed or build as you go with an excavator inside the bed reaching along the rows. Backfilling while assembling chambers rows as shown in the picture will help to ensure that equipment reach is not exceeded. Final Backfill of Chambers - Fill Material Install non -woven geotextile over stone. Geotextile must overlap 24" (600 mm) where edges meet. Compact at 24" (600 mm) of fill. Roller travel parallel with rows. Only after chambers have been backfilled to top of chamber and with a minimum 12" (300 mm) of cover stone on top of chambers can skid loaders and small LGP dozers be used to final grade cover stone and backfill material in accordance with ground pressure limits in Table 2. Equipment must push material parallel to rows only. Never push perpendicular to rows. StormTech recommends the contractor inspect chamber rows before placing final backfill. Any chambers damaged by construction equipment shall be removed and replaced. Inserta Tee Detail CONVEYANCE PIPE MATERIAL MAY VARY (PVC, HDPE, ETC.) L INSERTA TEEiTnYEw-iYEiTnYi CONNECTIONW Ixl PLACE ADS PLUS WOVEN GEOTEXTILE(CENTERED ON INSERTA-TEE INLET) OVER BEDDING STONE FOR SCOUR PROTECTION AT SIDE INLET CONNECTIONS, GEOTEXTILE MUST EXTEND 6" (150 mm) PAST CHAMBER FOOT NOTE: PART NUMBERS WILL VARY BASED ON INLET PIPE MATERIALS. CONTACT STORMTECH FOR MORE INFORMATION. SECTION A -A DO NOT INSTALL INSERTA-TEE AT CHAMBERJOINTS A A INSERTA TEE TO BE INSTALLED, CENTERED OVER CORRUGATION SIDE VIEW MAX DIAMETER OF HEIGHT FROM BASE OF CHAMBER INSERTA TEE CHAMBER (X) MC-3500 12" (250 mm) 6" (150 MM) MC-4500 12" (250 mm) 8" (200 mm) INSERTA TEE FITTINGS AVAILABLE FOR SDR 26, SDR 35, SCH 40 IPS GASKETED & SOLVENT WELD, N-12, HP STORM, C-900 OR DUCTILE IRON 4 Table 1- Acceptable Fill Materials @Final Fill: Fill Material for layer'D' Any soil/rock materials, N/A Prepare per site design engineer's starts from the top of the 'C' layer to the native soils or per plans. Paved installations may have bottom of flexible pavement or unpaved engineer's plans. Check stringent material and preparation finished grade above. Note that the plans for pavement requirements. pavement subbase may be part of the subgrade requirements. 'D' layer. ©Initial Fill: Fill Material for layer'C' Granular well -graded AASHTO M145 Begin compaction after min. 24" (600 starts from the top of the embedment soil/aggregate mixtures, A-1, A-2-4, A-3 mm) of material over the chambers stone ('B' layer) to 24" (600 mm) above <35%fInes or processed or is reached. Compact additional layers the top of the chamber. Note that aggregate. Most AASHTO M431 in 12" (300 mm) max. lifts to a min. pavement subbase may be part of the pavement subbase 3, 357, 4, 467, 5, 56, 95% Proctor density for well -graded 'C' layer. materials can be used in 57, 6, 67, 68, 7, 78, 8, material and 95% relative densityfor lieu of this layer. 89, 9,10 processed aggregate materials. ©Embedment Stone: Fill the Clean, crushed, angular AASHTO M431 No compaction required. surrounding chambers from the stone 3,4 foundation stone ('A' layer) to the 'C' layer above. AO Foundation Stone: Fill below Clean, crushed, angular AASHTO M431 Place and compact in 9" (230 mm) chambers from the subgrade up to the stone, 3,4 max lifts using two full coverages with foot (bottom) of the chamber. a vibratory compactor 2'3 Please Note: 1. The listed AASHTO designations are for gradations only. The stone must also be clean, crushed, angular. For example, a specification for #4 stone would state: "clean, crushed, angular no. 4 (AASHTO M43) stone". 2. StormTech compaction requirements are met for'A' location materials when placed and compacted in 9" (230 mm) (max) lifts using two full coverages with a vibratory compactor. 3. Where infiltration surfaces may be comprised by compaction, for standard installations and standard design load conditions, a flat surface may be achieved by raking or dragging without compaction equipment. For special load designs, contact StormTech for compaction requirements. Figure 2 - Fill Material Locations PERIMETER STONE EXCAVATION WALL (CAN BE SLOPED OR VERTICAL: MC-4500 - 12" MC-3500 - 6" ADS GEOSYNTHETICS 601T NON -WOVEN GEOTEXTILE ALL AROUND CLEAN, CRUSHED, ANGULAR STONE IN A & B LAYERS SUBGRADE SOILS Figure 1- Inspection Port Detail CONCRETE PAVEM CONCRETE SL 6" (150 mm) N THICKNE: STORMTECH CHAMBER 12" (300 mm) MIN WIDTH ONCRETE COLLAR NOT REQUIRED )R UNPAVED APPLICATIONS 8" NYLOPLAST INSPECTION PORT BODY (PART# 2708AG41PKIT) OR TRAFFIC RATED BOX W/SOLID LOCKING COVER 4" (100 mm) SDR 35 PIPE 4" (100 mm) INSERTA TEE TO BE CENTERED ON CORRUGATION VALLEY NOTE: INSPECTION PORTS MAY BE CONNECTED THROUGH ANY CHAMBER CORRUGATION VALLEY. PAVEMENT LAYER (DESIGNED BY SITE DESIGN ENGINEER) D \���\��\� \���\� 'TO BOTTOM OFFLEIHBLEPAVEMENT_FIX211NPAVEO \yi ���%C�\y/, INSTALLATIONS WHERE RIITTIN G FROM VEHICLES MAY OCCBR,�MC-4500-24" MC-4500-7.0' 2.1 m MAX CH INCREASECOVERTOaa• somm) 600mm ( ) �o/i u�� /i a /i u�� it _ _ _ _ _ • u�� , ( ) MIN MC-3500 - 18" (450 mm) MIN MC-3500 - 8.0' (2.4 m) MAX O12" (300 mm) MIN B 1 1 MC-4500 - 60" (1525 mm) MC-3500 - 45" (1140 mm) IIII IIIIIII IIIIIIIIIIIII II III - - - - DEPTH STONE TO BE DETERMINED D BY SITE DESIGN ENGINEER 9" (230 mm) MIN MC 4500 - 9" (230 Rim) IMIIINII II IIMCI45001 I11100" (2540 mm) 12" (300 mm) MIN MC 3500 - 6' (150 mm) MIN `MC-3500 - 77" (1950 mm) 5 Notes: Table 2 - Maximum Allowable Construction Vehicle Loads6 1.36" (900 mm) of stabilized cover materials over the chambers is recommended during the construction phase if general construction activities, such as full dump truck travel and dumping, are to occur over the bed. 2. During paving operations, dump truck axle loads on 18" (450mm) of cover for MC-3500s may be necessary. Precautions should be taken to avoid rutting of the road base layer, to ensure that compaction requirements have been met, and that a minimum of 18" (450mm) of cover for MC-3500s exists over the chambers. Contact StormTech for additional guidance on allowable axle loads during paving. 3. Ground pressure for track dozers is the vehicle operating weight divided by total ground contact area for both tracks. Excavators will exert higher ground pressures based on loaded bucket weight and boom extension. Final Fill Material ©Initial Fill Material 4. Mini -excavators (<8,000lbs/3,628 kg) can be used with at least 12" (300 mm) of stone over ®Embedment the chambers and are limited by the maximum Stone ground pressures in Table 2 based on a full bucket at maximum boom extension. 5. StormTech does not require compaction of initial fill at 18" (450 mm) of cover. However, requirements by others for 6" (150 mm) lifts may necessitate the use of small compactors at 18" (450 mm) of cover. 6. Storage of materials such as construction materials, equipment, spoils, etc. should not be located over the StormTech system. The use of equipment over the StormTech system not covered in Table 2 (ex. soil mixing equipment, cranes, etc) is limited. Please contact StormTech for more information. 36" (900) 32,000 (142) 16,000 (71) 12" (305) 4050 (194) 38,000 (169) Compacted (610) (102) 24" 2130 30" (762) 1770 (84) 36" (914) 1530 (73) 24" (600) 32,000 (142) 16,000 (71) 12" (305) 2750 (131) 20,000 (89) Compacted 24" (610) 1520 (73) 30" (762) 1310 (63) 36" (914) 1180 (56) 24" (600) MC-3500 12" (305) 2430 (116) 16,000 (71) Loose/Dumped 32,000 (142) 16,000 (71) 18" (457) 1730 (82) MC 4500 24" (610) 30" (762) 1390 (66) 1210 (58) 24,000 (107) 12,000 (53) 36" (914) 1100 (52) 18" (450) MC-3500 12" (305) 2140 (102) 5,000 (22) 32,000 (142) 16,000 (71) 18" (457) 1530 (73) (static loads only)' MC 4500 24" (610) 30" (762) 1260 (60) 1120 (53) 24,000 (107) 12,000 (53) 36" (914) 1030 (49) 12" (300) Not Allowed Not Allowed 12" (305) 1100 (53) Not Allowed 18" (457) 710 (34) 24" (610) 660 (32) 30" (762) 580 (28) 6" (150) Not Allowed Not Allowed Not Allowed Not Allowed Not Allowed Table 3 - Placement Methods and Descriptions (0) Final Fill A variety of placement methods may 36" (900 mm) minimum Dozers to push parallel to Roller travel parallel to rows Material be used All construction loads must cover required for dump rows ° only until 36" (900 mm) not exceed the maximum limits in trucks to dump over compacted cover is Table 2. chambers. reached. ®Initial Fill Material 7. Allowable track loads based on vehicle travel only. Excavators shall not operate on chamber beds © Embedment until the total backfill reaches 3 feet (900 mm) Stone over the entire bed. Call StormTech at 888.892.2694 for technical and product information or visit www.stormtech.com AAWStormTech Excavator positioned off bed recom- mended. Small excavator allowed over chambers. Small dozer allowed. No equipment allowed on bare chambers. Use excavator or stone conveyor positioned off bed or on foundation stone to evenly fill around all chambers to at least the top of chambers. Asphalt can be dumped into paver when compacted pavement subbase reaches 24" (600 mm) above top of chambers. No wheel loads allowed. Material must be placed outside the limits of the chamber bed. Small LGP track dozers & skid loaders allowed to grade cover stone with at least 12" (300 mm) stone under tracks at all times. Equipment must push par- allel to rows at all times. No tracked equipment is allowed on chambers until a min. 12" (300 mm) cover stone is in place. Use dynamic force of roller only after compacted fill depth reaches 24" (600 mm) over chambers. Roller travel parallel to chamber rows only. No rollers allowed. (Z) Foundation No StormTech restrictions. Contractor responsible for any conditions or requirements by others relative to subgrade bearing Stone capacity, dewatering or protection of subgrade. 6 17.0 Standard Limited Warranty StormTech® STANDARD LIMITED WARRANTY OF STORMTECH LLC ("STORMTECH"): PRODUCTS (A) This Limited Warranty applies solely to the StormTech (F) chambers and end plates manufactured by StormTech and sold to the original purchaser (the "Purchaser"). The chambers and end plates are collectively referred to as the "Products." (B) The structural integrity of the Products, when installed strictly in accordance with StormTech's written installation instructions at the time of installation, are warranted to the Purchaser against defective materials and workmanship for one (1) year from the date of purchase. Should a defect appear in the Limited Warranty period, the Purchaser shall provide StormTech with written notice of the alleged defect at StormTech's corporate headquarters within ten (10) days of the discovery of the defect. The notice shall describe the alleged defect in reasonable detail. StormTech agrees to supply replacements for those Products determined by StormTech to be defective and covered by this Limited Warranty. The supply of replacement products is the sole remedy of the Purchaser for breaches of this Limited Warranty. StormTech's liability specifically excludes the cost of removal and/or installation of the Products. (C) THIS LIMITED WARRANTY IS EXCLUSIVE. THERE ARE NO OTHER WARRANTIES WITH RESPECT TO THE PRODUCTS, INCLUDING NO IMPLIED WARRANTIES OF MERCHANTABILITY OR OF FITNESS FOR A PARTICULAR PURPOSE. (D) This Limited Warranty only applies to the Products when the Products are installed in a single layer. UNDER NO CIRCUMSTANCES, SHALL THE PRODUCTS BE INSTALLED IN A MULTI -LAYER CONFIGURATION. (E) No representative of StormTech has the authority to change this Limited Warranty in any manner or to extend this Limited Warranty. This Limited Warranty does not apply to any person other than to the Purchaser. Under no circumstances shall StormTech be liable to the Purchaser or to any third party for product liability claims; claims arising from the design, shipment, or installation of the Products, or the cost of other goods or services related to the purchase and installation of the Products. For this Limited Warranty to apply, the Products must be installed in accordance with all site conditions required by state and local codes; all other applicable laws; and StormTech's written installation instructions. (G) THE LIMITED WARRANTY DOES NOT EXTEND TO INCIDENTAL, CONSEQUENTIAL, SPECIAL OR INDIRECT DAMAGES. STORMTECH SHALL NOT BE LIABLE FOR PENALTIES OR LIQUIDATED DAMAGES, INCLUDING LOSS OF PRODUCTION AND PROFITS; LABOR AND MATERIALS; OVERHEAD COSTS; OR OTHER LOSS OR EXPENSE INCURRED BY THE PURCHASER OR ANY THIRD PARTY. SPECIFICALLY EXCLUDED FROM LIMITED WARRANTY COVERAGE ARE DAMAGE TO THE PRODUCTS ARISING FROM ORDINARY WEAR AND TEAR; ALTERATION, ACCIDENT, MISUSE, ABUSE OR NEGLECT, THE PRODUCTS BEING SUBJECTED TO VEHICLE TRAFFIC OR OTHER CONDITIONS WHICH ARE NOT PERMITTED BY STORMTECH'S WRITTEN SPECIFICATIONS OR INSTALLATION INSTRUCTIONS; FAILURE TO MAINTAIN THE MINIMUM GROUND COVERS SET FORTH IN THE INSTALLATION INSTRUCTIONS; THE PLACEMENT OF IMPROPER MATERIALS INTO THE PRODUCTS; FAILURE OF THE PRODUCTS DUE TO IMPROPER SITING OR IMPROPER SIZING; OR ANY OTHER EVENT NOT CAUSED BY STORMTECH. A PRODUCT ALSO IS EXCLUDED FROM LIMITED WARRANTY COVERAGE IF SUCH PRODUCT IS USED IN A PROJECT OR SYSTEM IN WHICH ANY GEOTEXTILE PRODUCTS OTHER THAN THOSE PROVIDED BY ADVANCED DRAINAGE SYSTEMS ARE USED. THIS LIMITED WARRANTY REPRESENTS STORMTECH'S SOLE LIABILITY TO THE PURCHASER FOR CLAIMS RELATED TO THE PRODUCTS, WHETHER THE CLAIM IS BASED UPON CONTRACT, TORT, OR OTHER LEGAL THEORY. 41 StormTech® Detention • Retention . Water Quality An company 20 Beaver Road, Suite 104 I Wethersfield I Connecticut 106109 888.892.2694 fax 866.328.8401 www.stormtech.com 1111111 m9m, GEOSYNTHEl'ICS ADS GEOSYNTHETICS 0601T NONWOVEN GEOTEXTILE Scope This specification describes ADS Geosynthetics 6.0 oz (0601T) nonwoven geotextile. Filter Fabric Requirements ADS Geosynthetics 6.0 oz (0601T) is a needle -punched nonwoven geotextile made of 100% polypropylene staple fibers, which are formed into a random network for dimensional stability. ADS Geosynthetics 6.0 oz (0601T) resists ultraviolet deterioration, rotting, biological degradation, naturally encountered basics and acids. Polypropylene is stable within a pH range of 2 to 13. ADS Geosynthetics 6.0 oz (0601T) conforms to the physical property values listed below: Filter Fabric Properties PROPERTY TEST METHOD UNIT M.A.R.V. (Minimum Average Roll Value) Weight (Typical) ASTM D 5261 oz/yd2 (g/m2) 6.0(203) Grab Tensile ASTM D 4632 Ibs (kN) 160 (0.711) Grab Elongation ASTM D 4632 % 50 Trapezoid Tear Strength ASTM D 4533 Ibs (kN) 60 (0.267) CBR Puncture Resistance ASTM D 6241 Ibs (kN) 410 (1.82) Permittivity* ASTM D 4491 sec' 1.5 Water Flow* ASTM D 4491 gpm/ft2 (Vmin/m2) 110 (4480) AOS* ASTM D 4751 US Sieve (mm) 70 (0.212) UV Resistance ASTM D 4355 %/hrs 70/500 PACKAGING Roll Dimensions (W x L) — ft 12.5 x 360 / 15 x 300 Square Yards Per Roll 500 Estimated Roll Weight — Ibs 195 " At the time of manufacturing. Handling may change these properties. ADS "Terms and Conditions of Sale" can be found on the ADS webs ite, www.ads-pipe.com Advanced Drainage Systems and the ADS logo is a registered trademark of Advanced Drainage Systems, Inc. ©Advanced Drainage Systems, Inc. #0601T 02/12 1111111 m9m, GEOSYNTHEl'ICS ADS GEOSYNTHETICS 315W WOVEN GEOTEXTILE Scope This specification describes ADS Geosynthetics 315W woven geotextile. Filter Fabric Requirements ADS Geosynthetics 315W is manufactured using high tenacity polypropylene yarns that are woven to form a dimensionally stable network, which allows the yarns to maintain their relative position. ADS Geosynthetics 315W resists ultraviolet deterioration, rotting and biological degradation and is inert to commonly encountered soil chemicals. ADS Geosynthetics 315W conforms to the physical property values listed below: Filter Fabric Properties PROPERTY TEST METHOD ENGLISH M.A.R.V. (Minimum Average Roll Value) METRIC M.A.R.V. (Minimum Average Roll Value) Tensile Strength (Grab) ASTM D-4632 315 Ibs 1400 N Elongation ASTM D-4632 15% 15% CBR Puncture ASTM D-6241 900 Ibs 4005 N Puncture ASTM D-4833 150 Ibs 667 N Mullen Burst ASTM D-3786 600 psi 4134 kPa Trapezoidal Tear ASTM D-4533 120 Ibs 533 N UV Resistance (at 500 hrs) ASTM D-4355 70% 70% Apparent Opening Size (AOS)* ASTM D-4751 40 US Std. Sieve 0.425 mm Permittivity ASTM D-4491 .05 sec' .05 sec' Water Flow Rate ASTM D-4491 4 gpm/ft2 163 I/min/m2 Roll Sizes 12.5'x360' 15.0' x 300' 17.5'x258' 3.81 mx109.8m 4.57 m x 91.5 m 5.33mx78.6m "Maximum average roll value. ADS "Terms and Conditions of Sale" can be found on the ADS website, www.ads-pipe.com Advanced Drainage Systems and the ADS logo is a registered trademark of Advanced Drainage Systems, Inc. ©Advanced Drainage Systems, Inc. #315W 02/12