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*Repair of underground tanks should be performed only by a qualified professional. | *Repair of underground tanks should be performed only by a qualified professional. | ||
*Tanks may crack if post-installation above ground loads are higher than load rating (equipment, vehicles) or if activities such as landscaping do not take into account the tank specification or limitations. | *Tanks may crack if post-installation above ground loads are higher than load rating (equipment, vehicles) or if activities such as landscaping do not take into account the tank specification or limitations. | ||
− | For additional information on inspection schedules and activities for underground systems see Section 3.5 of [ | + | For additional information on inspection schedules and activities for underground systems see Section 3.5 of [https://www1.nyc.gov/assets/dep/downloads/pdf/water/stormwater/stormwater-design-construction-guidelines-2012-final.pdf New York City’s Guidelines for the Design and Construction of Stormwater Management Systems]. |
===Stormwater ponds=== | ===Stormwater ponds=== | ||
Line 96: | Line 96: | ||
*Clogging or damage at overflow/bypass intakes will cause water to short-circuit the system which may result in damage to nearby structures. | *Clogging or damage at overflow/bypass intakes will cause water to short-circuit the system which may result in damage to nearby structures. | ||
*Overactive overflow/bypass systems may be an indication of maintenance needs upstream in the system, for example, a pump failure that is preventing the storage from being drawn down or storage capacity compromised by accumulated sediment | *Overactive overflow/bypass systems may be an indication of maintenance needs upstream in the system, for example, a pump failure that is preventing the storage from being drawn down or storage capacity compromised by accumulated sediment | ||
− | Additional information can be found in Section 6.5, Overflow provision and stormwater management, Management Guidelines, [ | + | Additional information can be found in Section 6.5, Overflow provision and stormwater management, Management Guidelines, [https://www.harvesth2o.com/adobe_files/ONTARIO_RWH_HANDBOOK_2010.pdf Ontario Guidelines for Residential Rainwater Harvesting Systems]. |
==Winter decommissioning and maintenance== | ==Winter decommissioning and maintenance== | ||
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*Despins, Christopher. September 2012. [https://www.crd.bc.ca/docs/default-source/water-pdf/cmhcrainwaterhandbook.pdf?sfvrsn=67aa96c9_2 Guidelines for Residential Rainwater Harvesting Systems Handbook]. Canada Mortgage and Housing Corporation (CMHC). ISBN 978-1-100-21183-1. | *Despins, Christopher. September 2012. [https://www.crd.bc.ca/docs/default-source/water-pdf/cmhcrainwaterhandbook.pdf?sfvrsn=67aa96c9_2 Guidelines for Residential Rainwater Harvesting Systems Handbook]. Canada Mortgage and Housing Corporation (CMHC). ISBN 978-1-100-21183-1. | ||
*North Carolina Department of Environmental Quality (NC DEQ). April 2014. [https://deq.nc.gov/about/divisions/energy-mineral-and-land-resources/stormwater/stormwater-program/stormwater-design North Carolina Stormwater BMP Manual], Chapter 25, Rainwater Harvesting. Draft document. | *North Carolina Department of Environmental Quality (NC DEQ). April 2014. [https://deq.nc.gov/about/divisions/energy-mineral-and-land-resources/stormwater/stormwater-program/stormwater-design North Carolina Stormwater BMP Manual], Chapter 25, Rainwater Harvesting. Draft document. | ||
+ | |||
+ | <noinclude> | ||
+ | ==Related pages== | ||
+ | ===Rainwater harvest and reuse=== | ||
+ | *[[Overview for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[[Design criteria for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[[Construction specifications for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[[Operation and maintenance for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[[Water quality considerations for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[[Environmental concerns for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[[Cost-benefit considerations for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[[Case studies for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[[Calculating credits for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[[Definitions for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[https://stormwater.pca.state.mn.us/index.php?title=Requirements,_recommendations_and_information_for_using_Harvest_and_re-use/cistern_as_a_BMP_in_the_MIDS_calculator Requirements, recommendations and information for using Harvest and re-use/cistern as a BMP in the MIDS calculator] | ||
+ | *[[Links for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[[References for stormwater and rainwater harvest and use/reuse]] | ||
+ | *[[Technical support for stormwater and rainwater harvest and use/reuse]] | ||
+ | ===Green Infrastructure=== | ||
+ | *[[Green Stormwater Infrastructure (GSI) and sustainable stormwater management]] | ||
+ | *Operation and maintenance of green infrastructure practices | ||
+ | **[[Operation and maintenance of bioretention and other stormwater infiltration practices]] | ||
+ | **[[Operation and maintenance of bioretention and other stormwater infiltration practices - supplemental information]] | ||
+ | **[[Operation and maintenance (O&M) of tree trenches and tree boxes]] | ||
+ | **[[Operation and maintenance of tree trenches and tree boxes - supplemental information]] | ||
+ | **[[Operation and maintenance (O&M) of green roofs]] | ||
+ | **[[Operation and maintenance of green roofs - supplemental information]] | ||
+ | **[[Operation and maintenance (O&M) of swales]] | ||
+ | **[[Operation and maintenance of swales - supplemental information]] | ||
+ | **[[Operation and maintenance (O&M) of filter strips]] | ||
+ | **[[Operation and maintenance of filter strips - supplemental information]] | ||
+ | **[[Operation and maintenance (O&M) of stormwater and rainwater harvest and use/reuse practices]] | ||
+ | **[[Operation and maintenance (O&M) of stormwater and rainwater harvest and use/reuse practices - supplemental information]] | ||
+ | **[[Operation and maintenance (O&M) of stormwater treatment wetland practices]] | ||
+ | **[[Operation and maintenance (O&M) of permeable pavement]] | ||
+ | **[[Operation and maintenance (O&M) of permeable pavement - supplemental information]] | ||
+ | |||
+ | [[Category:Level 3 - Best management practices/Nonstructural practices/Harvest and reuse]] | ||
+ | [[Category:Level 3 - Best management practices/Specifications and details/Operation and maintenance]] | ||
+ | </noinclude> |
This page provides supplemental information on operation and maintenance (O&M) of stormwater and rainwater harvest and use/reuse practices. For basic information on O&M for stormwater and rainwater harvest and use/reuse practices, see Operation and maintenance (O&M) of stormwater and rainwater harvest and use/reuse practices.
Operation and maintenance plans will vary depending on the configuration and components of the harvest and use system. Operation and maintenance considerations are described by system component below. Guidelines for inspection and maintenance timeframes and activities are provided in the following table: General Inspection and maintenance guidelines for stormwater harvest and use systems.
Collection surfaces should be inspected to identify sources of contamination and determine maintenance needs. Source control of pollutants and large debris at collection surfaces improves the quality of harvested water and can also extend the maintenance life of downstream components by reducing sediment and associated pollutant loads delivered to conveyances.
Rooftops should be kept free and clear of debris Organic debris from trees (leaves, pollen, flowers, seeds, twigs, etc.) can degrade the quality of harvested water. Overhanging tree branches should be trimmed as needed to reduce these inputs. Animal feces can degrade water quality. Any nests should be removed and measures to discourage animal activity should be implemented as possible. Rooftops should be kept in good repair Roof material may degrade over time due to exposure to UV light, repeated freeze-thaw cycles or accumulated storm damage. This may negatively impact the quality of harvested water (TWBD, 2010).
Maintain healthy vegetation and minimize application of chemicals to protect water quality Monitor for land disturbance and provide erosion and sediment control.
Residual de-icing chemicals, sand, and salt should be cleaned from paved surfaces prior to spring startup of the system Pavement should be swept regularly (generally once per month) Any spills on the pavement should be cleaned immediately and/or contained to prevent contamination of runoff collected in the storage unit.
Collection systems should be kept free of debris to prevent clogging and should be inspected to identify leaks. Clogging decreases the capture efficiency of the harvest and use system and can result in flooding or damage to collection surfaces or upstream facilities. Debris that has built up in conveyances may act as a source of pollution in harvested water, increasing the burden on downstream water treatment components to meet end use water quality criteria. Leaks in the system also decrease the capture efficiency of the system and may cause damage to foundations or structures located near the collection system.
The primary function of pre-storage treatment components is to reduce sediment and adhered pollutant loads in harvested water. Since primary treatment components are designed to collect sediment, these components must be inspected and maintained to preserve sediment storage capacity and maintain functionality of the collection system.
Collection systems are often designed in a passive form using gravity, so operational needs are limited. If collection systems include pumps, then the needs would be similar for distribution systems.
Gutter and downspouts can be damaged by high winds, ice dams, or intense storms. Additional inspection is recommended following very large storms or extreme conditions. Leaves, twigs, and other organic debris should be removed from screens at a minimum in the spring and fall, but additional cleaning may be required where there is significant tree canopy.
Ground surface collection systems should be inspected annually for debris accumulation and erosion and repaired as needed.
Sediment and debris accumulations in pretreatment storage components should be monitored periodically during the first year of operation to determine the rate of accumulation and develop an appropriate sediment removal schedule. Joints and fittings which connect collection and pre-storage treatment components should be inspected annually to look for loose fittings and leaks.
Collection, distribution, makeup supply, and overflow systems all interact with the storage unit in some capacity. For this reason, regular inspection and monitoring of the storage system is an important diagnostic tool for monitoring system function as a whole.
Special consideration may be needed for underground systems
For additional information on inspection schedules and activities for underground systems see Section 3.5 of New York City’s Guidelines for the Design and Construction of Stormwater Management Systems.
For information on the monitoring and maintenance of stormwater ponds see the MN Stormwater Manual section on operation and maintenance of stormwater ponds.
Post-storage treatment systems generally include consumable components – filters, bulbs, chemicals – that must be periodically cleaned, replaced, or replenished to maintain the performance of the water treatment system. Maintenance considerations will vary depending on the number and kind of treatment components that are included in the system. Examples include cartridge filters, reverse osmosis filters, UV disinfection light bulbs, ozone disinfection, and chlorine disinfection. See Table 6.5 of the Texas Rainwater Harvesting Manual for additional information.
Monitoring, maintenance, and repair of pumps, pipes, and controls may require a certified or licensed professional. The O&M plan should outline the conditions under which a licensed professional is needed.
Most often a problem with the pump and pressurized distribution system is due to associated components (water level sensor, valves, pressure tank, makeup supply, or automatic bypass) and not the pump itself (Despins, 2012). Problems with associated components might be diagnosed by evaluating the water level in the tank and operation of these components (Is the tank empty when it shouldn’t be? Is the makeup supply on or off when it shouldn’t be?). Maintenance concerns will vary depending on the type of pump (e.g. submersible or non-submersible). Potential maintenance concerns for pumps include the following.
Overflow must be monitored periodically after rainfall events to ensure the system is capturing events it was designed to capture. Overflows that are not functioning properly may cause erosion, flooding, or damage to control systems (makeup supply, pump controls). Specific issues include the following.
Additional information can be found in Section 6.5, Overflow provision and stormwater management, Management Guidelines, Ontario Guidelines for Residential Rainwater Harvesting Systems.
Throughout Minnesota, temperatures can drop below freezing (0°C) during the winter months. If stormwater harvesting systems are not fully winterized to withstand seasonal temperature fluctuations, systems should be decommissioned before the cold weather season. Winter decommissioning also provides an opportunity to preform annual inspection and maintenance. The table below provides a summary of winter decommissioning and maintenance tasks.
Link to this table
Component | Typical decommissioning and winter maintenance tasks needed prior to spring startup 1 |
---|---|
Source Area/Collection Surface |
|
Collection System |
|
Storage System |
|
Treatment System |
|
Distribution System |
|
Overflow/Bypass Systems |
|
This page was last edited on 28 January 2023, at 17:15.