Stormwater harvesting

Last updated April 02, 2024

Stormwater harvesting or stormwater reuse is the collection, accumulation, treatment or purification, and storage of stormwater for its eventual reuse. While rainwater harvesting collects precipitation primarily from rooftops, stormwater harvesting deals with collection of runoff from creeks, gullies, ephemeral streams and underground conveyance. It can also include catchment areas from developed surfaces, such as roads or parking lots, or other urban environments such as parks, gardens and playing fields.

Water that comes into contact with impervious surfaces, or saturated surfaces incapable of absorbing more water, is termed surface runoff. As the surface runoff travels greater distance over impervious surfaces it often becomes contaminated and collects an increasing amount of pollutants. A main challenge of stormwater harvesting is the removal of pollutants in order to make this water available for reuse.^[1]

Stormwater harvesting projects often have multiple objectives, such as reducing contaminated runoff to sensitive waters, promoting groundwater recharge, and non-potable applications such as toilet flushing and irrigation.^[2] Stormwater harvesting is also practiced in areas of the United States as a way to address rising water demands as population rises.^[2] Internationally, Australia is notable in its active pursuit of stormwater harvesting.

Ground catchment system CatchingHillRunoffwater.svg — Ground catchment system

Systems

Ground catchments systems channel water from a prepared catchment area into storage. These systems are often considered in areas where rainwater is scarce and other sources of water are not available. If properly designed, ground catchment systems can collect large quantities of rainwater. In arid ranch land, a catchwater or cattle tank can be constructed across shallow ephemeral washes to impound and collect what little stormwater does generate there. This untreated water is easily accessed and utilized by livestock. More intricate collection and processing systems are necessary for stormwater harvest to be reused for human uses.

Stormwater capture

Five Core Steps: End Use, Collection, Treatment, Storage, and Distribution^[3]

End Use
- Water resources become more scarce as the human population grows. Populations need to create systems and methods to minimize water consumption at all levels, while simultaneously engineering new methods of water reuse. For non-potable water purposes with lower water quality needs, people can use stormwater for toilet flushing, gardening, fire fighting, irrigation , etc. For potable water use of higher water quality, stormwater needs to be highly treated before final use. The latter has rarely been used around the world.^[1] Some stormwater collection systems aim to simply reduce the amount of stormwater runoff that flows to a nearby waterway. The benefits of these systems include reducing pollution^[4] in streams, lakes, and nearshore coastal environments, as well as promoting groundwater recharge. The intended end use of a system will determine the level of treatment and processing of collected stormwater.
Collections
- Stormwater collection is a process of directing water into storage from stormwater gathering, such as urban runoff. Generally, there are two types, online storages and offline storages. Online storages are a conventional way of acquiring stormwater directly from waterways or drains. For instance, the urban drainage system of channels and pipes conduct stormwater into storage facilities,^[5] often with treatment at or just prior to storage. One drawback of this collection design is the required maintenance that systems may require for structural integrity to prevent conduit failure resulting in stormwater leakage. Water Sensitive Urban Design, or WSUD , is one comprehensive planning and design process that incorporates online stormwater storage into urban development models. Offline storages require additional facilities to conduct water from waterways indirectly, and can serve as storage for stormwater prior to treatment.^[6] For instance, weirs divert flows into stormwater containment and contribute to a large part of stormwater catchment for a city, where it is then stored for future treatment and distribution. Stormwater collection is widely practiced for purposes of urban runoff and flood mitigation as well.^[7]
Treatment
- Dissolved Air Floatation Treatment at the Santa Monica Urban Runoff Recycling Facility
  Stormwater treatment is the greatest challenge for stormwater harvesting. Water treatment processes depend on the intended end use and the catchment equipment, which determines the level of pollutants to be filtered and removed. For instance, construction uses may only require non-potable water where the water processing includes only filtration and disinfection. However, for potable uses of higher water quality, the treatment process requires screening, coagulation, filtration, carbon adsorption, and disinfection.
Storage
- There are three factors to consider in terms of storage: function, location, and capacity. The planner is responsible for determining the end use of the stored stormwater, such as fire fighting, industrial water supply, farming and irrigation, recreation, flood mitigation , groundwater recharge, etc. Regarding location of a system and its storage, a water tank in proximity to the waters' end use may be the best design. If the collection system is intended to slow runoff and/or recharge an aquifer, an on-site, below ground infiltration systems may be considered.^[8] Choices between online and offline storages can affect the surrounding natural aquatic systems and yields different maintenance costs and flood mitigation effectiveness. The capacity of a storage system will be determined by the type of end use in a particular climate or period of time.
Distribution
- Generally, there are two types of stormwater distribution systems. The first is open space irrigation systems.^[9] This application uses treated stormwater to irrigate open spaces such as parks, municipal green spaces, golf courses, etc., and can be implemented at a hyper-local scale (ie catchment and reuse occurs at the same park). Another system is a non-potable distribution system which distributes treated stormwater to be used for things like toilet flushing, fire fighting, and some industrial uses. This system may require additional infrastructure such as a third-pipe network for distribution.

Concerns

Major concerns for stormwater harvesting projects include cost effectiveness as well as quality, quantity, and reliability of the reclamation, as well as existing water management infrastructure and soil characteristics. Some projects have estimated stormwater harvesting to be twice as expensive per unit -when including operating costs- versus other potable water alternatives. New construction of third-pipe networks in urban settings can be prohibitively expensive; therefore the ideal project will produce recycled stormwater of potable quality in order to take advantage of existing distribution infrastructure. Attaining quality as well as useful quantity water from stormwater harvesting presents challenges of filtration efficacy as well as source reliability and predictability. However, other valuable (and hard-to-calculate) benefits include reducing soil erosion by slowing flow rates and reducing demands on local aquifers, as well as reduction of pollution into local waterways.

Related Research Articles

Stormwater, also written storm water, is water that originates from precipitation (storm), including heavy rain and meltwater from hail and snow. Stormwater can soak into the soil (infiltrate) and become groundwater, be stored on depressed land surface in ponds and puddles, evaporate back into the atmosphere, or contribute to surface runoff. Most runoff is conveyed directly as surface water to nearby streams, rivers or other large water bodies without treatment.

Greywater refers to domestic wastewater generated in households or office buildings from streams without fecal contamination, i.e., all streams except for the wastewater from toilets. Sources of greywater include sinks, showers, baths, washing machines or dishwashers. As greywater contains fewer pathogens than blackwater, it is generally safer to handle and easier to treat and reuse onsite for toilet flushing, landscape or crop irrigation, and other non-potable uses. Greywater may still have some pathogen content from laundering soiled clothing or cleaning the anal area in the shower or bath.

Water reclamation is the process of converting municipal wastewater (sewage) or industrial wastewater into water that can be reused for a variety of purposes. Types of reuse include: urban reuse, agricultural reuse (irrigation), environmental reuse, industrial reuse, planned potable reuse, and de facto wastewater reuse. For example, reuse may include irrigation of gardens and agricultural fields or replenishing surface water and groundwater. Reused water may also be directed toward fulfilling certain needs in residences, businesses, and industry, and could even be treated to reach drinking water standards. The injection of reclaimed water into the water supply distribution system is known as direct potable reuse. However, drinking reclaimed water is not a typical practice. Treated municipal wastewater reuse for irrigation is a long-established practice, especially in arid countries. Reusing wastewater as part of sustainable water management allows water to remain as an alternative water source for human activities. This can reduce scarcity and alleviate pressures on groundwater and other natural water bodies.

<span class="mw-page-title-main">Rainwater harvesting</span> Accumulation of rainwater for reuse

Rainwater harvesting (RWH) is the collection and storage of rain, rather than allowing it to run off. Rainwater is collected from a roof like surface and redirected to a tank, cistern, deep pit, aquifer, or a reservoir with percolation, so that it seeps down and restores the ground water. Dew and fog can also be collected with nets or other tools. Rainwater harvesting differs from stormwater harvesting as the runoff is typically collected from roofs and other area surfaces for storage and subsequent reuse. Its uses include watering gardens, livestock, irrigation, domestic use with proper treatment, and domestic heating. The harvested water can also be committed to longer-term storage or groundwater recharge.

Bioswales are channels designed to concentrate and convey stormwater runoff while removing debris and pollution. Bioswales can also be beneficial in recharging groundwater.

A combined sewer is a type of gravity sewer with a system of pipes, tunnels, pump stations etc. to transport sewage and urban runoff together to a sewage treatment plant or disposal site. This means that during rain events, the sewage gets diluted, resulting in higher flowrates at the treatment site. Uncontaminated stormwater simply dilutes sewage, but runoff may dissolve or suspend virtually anything it contacts on roofs, streets, and storage yards. As rainfall travels over roofs and the ground, it may pick up various contaminants including soil particles and other sediment, heavy metals, organic compounds, animal waste, and oil and grease. Combined sewers may also receive dry weather drainage from landscape irrigation, construction dewatering, and washing buildings and sidewalks.

The United States Environmental Protection Agency (EPA) Storm Water Management Model (SWMM) is a dynamic rainfall–runoff–subsurface runoff simulation model used for single-event to long-term (continuous) simulation of the surface/subsurface hydrology quantity and quality from primarily urban/suburban areas.

Rain gardens, also called bioretention facilities, are one of a variety of practices designed to increase rain runoff reabsorption by the soil. They can also be used to treat polluted stormwater runoff. Rain gardens are designed landscape sites that reduce the flow rate, total quantity, and pollutant load of runoff from impervious urban areas like roofs, driveways, walkways, parking lots, and compacted lawn areas. Rain gardens rely on plants and natural or engineered soil medium to retain stormwater and increase the lag time of infiltration, while remediating and filtering pollutants carried by urban runoff. Rain gardens provide a method to reuse and optimize any rain that falls, reducing or avoiding the need for additional irrigation. A benefit of planting rain gardens is the consequential decrease in ambient air and water temperature, a mitigation that is especially effective in urban areas containing an abundance of impervious surfaces that absorb heat in a phenomenon known as the heat-island effect.

First flush is the initial surface runoff of a rainstorm. During this phase, water pollution entering storm drains in areas with high proportions of impervious surfaces is typically more concentrated compared to the remainder of the storm. Consequently, these high concentrations of urban runoff result in high levels of pollutants discharged from storm sewers to surface waters.

<span class="mw-page-title-main">Surface runoff</span> Flow of excess rainwater not infiltrating in the ground over its surface

Surface runoff is the unconfined flow of water over the ground surface, in contrast to channel runoff. It occurs when excess rainwater, stormwater, meltwater, or other sources, can no longer sufficiently rapidly infiltrate in the soil. This can occur when the soil is saturated by water to its full capacity, and the rain arrives more quickly than the soil can absorb it. Surface runoff often occurs because impervious areas do not allow water to soak into the ground. Furthermore, runoff can occur either through natural or human-made processes.

Sustainable drainage systems are a collection of water management practices that aim to align modern drainage systems with natural water processes and are part of a larger green infrastructure strategy. SuDS efforts make urban drainage systems more compatible with components of the natural water cycle such as storm surge overflows, soil percolation, and bio-filtration. These efforts hope to mitigate the effect human development has had or may have on the natural water cycle, particularly surface runoff and water pollution trends.

A rainwater tank is a water tank used to collect and store rain water runoff, typically from rooftops via pipes. Rainwater tanks are devices for collecting and maintaining harvested rain. A rainwater catchment or collection system can yield 2,358 litres (623 US gal) of water from 2.54 cm (1.00 in) of rain on a 92.9 m² (1,000 sq ft) roof.

Best management practices (BMPs) is a term used in the United States and Canada to describe a type of water pollution control. Historically the term has referred to auxiliary pollution controls in the fields of industrial wastewater control and municipal sewage control, while in stormwater management and wetland management, BMPs may refer to a principal control or treatment technique as well.

Urban runoff is surface runoff of rainwater, landscape irrigation, and car washing created by urbanization. Impervious surfaces are constructed during land development. During rain, storms, and other precipitation events, these surfaces, along with rooftops, carry polluted stormwater to storm drains, instead of allowing the water to percolate through soil. This causes lowering of the water table and flooding since the amount of water that remains on the surface is greater. Most municipal storm sewer systems discharge untreated stormwater to streams, rivers, and bays. This excess water can also make its way into people's properties through basement backups and seepage through building wall and floors.

Water resources are natural resources of water that are potentially useful for humans, for example as a source of drinking water supply or irrigation water. 97% of the water on Earth is salt water and only three percent is fresh water; slightly over two-thirds of this is frozen in glaciers and polar ice caps. The remaining unfrozen freshwater is found mainly as groundwater, with only a small fraction present above ground or in the air. Natural sources of fresh water include surface water, under river flow, groundwater and frozen water. Artificial sources of fresh water can include treated wastewater and desalinated seawater. Human uses of water resources include agricultural, industrial, household, recreational and environmental activities.

Aquifer storage and recovery (ASR) is the direct injection of surface water supplies such as potable water, reclaimed water, or river water into an aquifer for later recovery and use. The injection and extraction is often done by means of a well. In areas where the rainwater cannot percolate the soil or where it is not capable of percolating it fast enough and where the rainwater is thus diverted to rivers, rainwater ASR could help to keep the rainwater within an area. ASR is used for municipal, industrial and agricultural purposes.

Water-sensitive urban design (WSUD) is a land planning and engineering design approach which integrates the urban water cycle, including stormwater, groundwater, and wastewater management and water supply, into urban design to minimise environmental degradation and improve aesthetic and recreational appeal. WSUD is a term used in the Middle East and Australia and is similar to low-impact development (LID), a term used in the United States; and Sustainable Drainage System (SuDS), a term used in the United Kingdom.

Low-impact development (LID) is a term used in Canada and the United States to describe a land planning and engineering design approach to manage stormwater runoff as part of green infrastructure. LID emphasizes conservation and use of on-site natural features to protect water quality. This approach implements engineered small-scale hydrologic controls to replicate the pre-development hydrologic regime of watersheds through infiltrating, filtering, storing, evaporating, and detaining runoff close to its source. Green infrastructure investments are one approach that often yields multiple benefits and builds city resilience.

Rainwater harvesting is becoming a procedure that many Canadians are incorporating into their daily lives, although data does not give exact figures for implementation. Rainwater can be used for a number of purposes including stormwater reduction, irrigation, laundry and portable toilets. In addition to low costs, rainwater harvesting is useful for landscape irrigation. Many Canadians have started implementing rainwater harvesting systems for use in stormwater reduction, irrigation, laundry, and lavatory plumbing. Provincial and municipal legislation is in place for regulating the rights and uses for captured rainwater. Substantial reform to Canadian law since the mid-2000s has increased the use of this technology in agricultural, industrial, and residential use, but ambiguity remains amongst legislation in many provinces. Bylaws and local municipal codes often regulate rainwater harvesting.

Rainwater management is a series of countermeasures to reduce runoff volume and improve water quality by replicating the natural hydrology and water balance of a site, with consideration of rainwater harvesting, urban flood management and rainwater runoff pollution control.

References

1 2 McArdle, P; et al. (2011). "Centralised urban stormwater harvesting for potable use". Water Science and Technology. 63 (1): 16–24. doi:10.2166/wst.2011.003. PMID 21245548 – via Web of Science.
1 2 "Monterey-Pacific Grove ASBS Stormwater Management Project" (PDF). 2014. Retrieved November 8, 2020.
↑ McMahon, Joseph (October 2008). "Review of Stormwater Harvesting Practices". Urban Water Security Research Alliance Technical Report– via ResearchGate.
↑ Heyvaert, Alan C.; et al. (2006). "Subalpine, Cold Climate, Stormwater Treatment with a Constructed Surface Flow Wetland". Journal of the American Water Resources Association. 42 (1): 45–54. Bibcode:2006JAWRA..42...45H. doi:10.1111/j.1752-1688.2006.tb03822.x. S2CID 130764772.
↑ "Monterey-Pacific Grove ASBS Stormwater Management Project" (PDF). 2014. Retrieved November 8, 2020.
↑ Natural Resource Management Ministerial Council; et al. (2009). Australian Guidelines for Water Recycling: Stormwater Harvesting and Reuse (PDF). ISBN 978-1-921173-45-5 . Retrieved Nov 10, 2020.{{cite book}}: |website= ignored (help)
↑ "National Resource Council Report: Urban Stormwater Management in the United States" (PDF). Environmental Protection Agency. Retrieved October 23, 2020.
↑ "Villanova Pervious Concrete Site" (PDF). Retrieved November 8, 2020.
↑ Rahman, M.M. (2016). Use of Recycled Water for Irrigation of Open Spaces: Benefits and Risks. Springer, Cham. pp. Ch. 17. ISBN 978-3-319-28110-0.

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[:14-1] 1 2 McArdle, P; et al. (2011). "Centralised urban stormwater harvesting for potable use". Water Science and Technology. 63 (1): 16–24. doi:10.2166/wst.2011.003. PMID 21245548 – via Web of Science.

[:02-2] 1 2 "Monterey-Pacific Grove ASBS Stormwater Management Project" (PDF). 2014. Retrieved November 8, 2020.

[:1-3] McMahon, Joseph (October 2008). "Review of Stormwater Harvesting Practices". Urban Water Security Research Alliance Technical Report– via ResearchGate.

[4] Heyvaert, Alan C.; et al. (2006). "Subalpine, Cold Climate, Stormwater Treatment with a Constructed Surface Flow Wetland". Journal of the American Water Resources Association. 42 (1): 45–54. Bibcode:2006JAWRA..42...45H. doi:10.1111/j.1752-1688.2006.tb03822.x. S2CID 130764772.

[:03-5] "Monterey-Pacific Grove ASBS Stormwater Management Project" (PDF). 2014. Retrieved November 8, 2020.

[6] Natural Resource Management Ministerial Council; et al. (2009). Australian Guidelines for Water Recycling: Stormwater Harvesting and Reuse (PDF). ISBN 978-1-921173-45-5 . Retrieved Nov 10, 2020.{{cite book}}: |website= ignored (help)

[7] "National Resource Council Report: Urban Stormwater Management in the United States" (PDF). Environmental Protection Agency. Retrieved October 23, 2020.

[8] "Villanova Pervious Concrete Site" (PDF). Retrieved November 8, 2020.

[9] Rahman, M.M. (2016). Use of Recycled Water for Irrigation of Open Spaces: Benefits and Risks. Springer, Cham. pp. Ch. 17. ISBN 978-3-319-28110-0.

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v t e Stormwater management structures
Treatment / Containment	Biofilter Constructed wetland Detention basin Green roof Media filter Oil-grit separator Retention basin Stormwater detention vault Stormwater harvesting
Flow control	Continuous monitoring and adaptive control Flood control channel Flow control structure Hydrodynamic separator Storm drain
Infiltration	Bioretention Bioswale Dry well Infiltration basin Percolation trench Permeable paving Semicircular bund