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Sustainable drainage system

December 20, 2023

Sustainable drainage systems (also known as SuDS,[1] SUDS,[2][3] or sustainable urban drainage systems[4]) 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.[5] 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.[6]

Retention ponds such as this one in Dunfermline, Scotland, are considered components of a sustainable drainage system.

SuDS have become popular in recent decades as understanding of how urban development affects natural environments, as well as concern for climate change and sustainability, have increased. SuDS often use built components that mimic natural features in order to integrate urban drainage systems into the natural drainage systems or a site as efficiently and quickly as possible. SUDS infrastructure has become a large part of the Blue-Green Cities demonstration project in Newcastle upon Tyne.[7]

History of drainage systems edit

Drainage systems have been found in ancient cities over 5,000 years old, including Minoan, Indus, Persian, and Mesopotamian civilizations.[8] These drainage systems focused mostly on reducing nuisances from localized flooding and waste water. Rudimentary systems made from brick or stone channels constituted the extent of urban drainage technologies for centuries. Cities in Ancient Rome also employed drainage systems to protect low-lying areas from excess rainfall. When builders began constructing aqueducts to import fresh water into cities, urban drainage systems became integrated into water supply infrastructure for the first time as a unified urban water cycle.[9]

 
Bazzalgette combined sewer system being built in 1860, London

Modern drainage systems did not appear until the 19th century in Western Europe, although most of these systems were primarily built to deal with sewage issues rising from rapid urbanization. One such example is that of the London sewerage system, which was constructed to combat massive contamination of the River Thames. At the time, the River Thames was the primary component of London's drainage system, with human waste concentrating in the waters adjacent to the densely populated urban center. As a result, several epidemics plagued London's residents and even members of Parliament, including events known as the 1854 Broad Street cholera outbreak and the Great Stink of 1858.[10] The concern for public health and quality of life launched several initiatives, which ultimately led to the creation of London's modern sewerage system designed by Joseph Bazalgette.[11] This new system explicitly aimed to ensure waste water was redirected as far away from water supply sources as possible in order to reduce the threat of waterborne pathogens. Since then, most urban drainage systems have aimed for similar goals of preventing public health crises.

Within past decades, as climate change and urban flooding have become increasingly urgent challenges, drainage systems designed specifically for environmental sustainability have become more popular in both academia and practice. The first sustainable drainage system to utilize a full management train including source control in the UK was the Oxford services motorway station designed by SuDS specialists Robert Bray Associates[12] Originally the term SUDS described the UK approach to sustainable urban drainage systems. These developments may not necessarily be in "urban" areas, and thus the "urban" part of SuDS is now usually dropped to reduce confusion. Other countries have similar approaches in place using a different terminology such as best management practice (BMP) and low-impact development in the United States,[13] water-sensitive urban design (WSUD) in Australia,[14] low impact urban design and development (LIUDD) in New Zealand,[15] and comprehensive urban river basin management in Japan.[14]

The National Research Council's definitive report on urban stormwater management described that urban drainage systems began in the United States after World War II. These structures were based on simple catch basins and pipes to transfer the water outside of the cities.[16] Urban stormwater management started to evolve more in the 1970s when landscape architects focused more on low-impact development and began using practices such as infiltration channels.[16] Parallel to this time, scientists started becoming concerned with other stormwater hazards surrounding pollution. Studies such as the Nationwide Urban Runoff Program showed that urban runoff contained pollutants like heavy metals, sediments, and pathogens, all of which water can pick up as it flows off of impermeable surfaces.[17] It was at the beginning of the 21st century where stormwater infrastructure to allow runoff to infiltrate close to the source became popular. This was around the same time that the term green infrastructure was coined.[18]

Background edit

Traditional urban drainage systems are limited by various factors including volume capacity, damage or blockage from debris and contamination of drinking water. Many of these issues are addressed by SuDS systems by bypassing traditional drainage systems altogether and returning rainwater to natural water sources or streams as soon as possible. Increasing urbanisation has caused problems with increased flash flooding after sudden rain. As areas of vegetation are replaced by concrete, asphalt, or roofed structures, leading to impervious surfaces, the area loses its ability to absorb rainwater. This rain is instead directed into surface water drainage systems, often overloading them and causing floods.

The goal of all sustainable drainage systems is to use rainfall to recharge the water sources of a given site. These water sources are often underlying the water table, nearby streams, lakes, or other similar freshwater sources. For example, if a site is above an unconsolidated aquifer, then SuDS will aim to direct all rain that falls on the surface layer into the underground aquifer as quickly as possible. To accomplish this, SuDS use various forms of permeable layers to ensure the water is not captured or redirected to another location. Often these layers include soil and vegetation, though they can also be artificial materials.

The paradigm of SuDS solutions should be that of a system that is easy to manage, requiring little or no energy input (except from environmental sources such as sunlight, etc.), resilient to use, and being environmentally as well as aesthetically attractive. Examples of this type of system are basins (shallow landscape depressions that are dry most of the time when it is not raining), rain gardens (shallow landscape depressions with shrub or herbaceous planting), swales (shallow normally-dry, wide-based ditches), filter drains (gravel filled trench drain), bioretention basins (shallow depressions with gravel and/or sand filtration layers beneath the growing medium), reed beds and other wetland habitats that collect, store, and filter dirty water along with providing a habitat for wildlife.

A common misconception of SuDS is that they reduce flooding on the development site. In fact the SuDS is designed to reduce the impact that the surface water drainage system of one site has on other sites. For instance, sewer flooding is a problem in many places. Paving or building over land can result in flash flooding. This happens when flows entering a sewer exceed its capacity and it overflows. The SuDS system aims to minimise or eliminate discharges from the site, thus reducing the impact, the idea being that if all development sites incorporated SuDS then urban sewer flooding would be less of a problem. Unlike traditional urban stormwater drainage systems, SuDS can also help to protect and enhance ground water quality.

Example features edit

Because SuDS describe a collection of systems with similar components or goals, there is a large crossover between SuDS and other terminologies dealing with sustainable urban development.[19] The following are examples generally accepted as components in a SuDS system:

 
Roadside bioswale designed to filter storm water runoff from street surfaces

Bioswales

This section is an excerpt from Bioswale.[edit]
 
Runoff from the street flows directly into an adjacent bioswale

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

Bioswales are typically vegetated, mulched, or xeriscaped.[20] They consist of a swaled drainage course with gently sloped sides (less than 6%).[21]: 19  Bioswale design is intended to safely maximize the time water spends in the swale, which aids the collection and removal of pollutants, silt and debris. Depending on the site topography, the bioswale channel may be straight or meander. Check dams are also commonly added along the bioswale to increase stormwater infiltration. A bioswale's make-up can be influenced by many different variables, including climate, rainfall patterns, site size, budget, and vegetation suitability.

It is important to maintain bioswales to ensure the best possible efficiency and effectiveness in removal of pollutants from stormwater runoff. Planning for maintenance is an important step, which can include the introduction of filters or large rocks to prevent clogging. Annual maintenance through soil testing, visual inspection, and mechanical testing is also crucial to the health of a bioswale.

Bioswales are commonly applied along streets and around parking lots, where substantial automotive pollution settles on the pavement and is flushed by the first instance of rain, known as the first flush. Bioswales, or other types of biofilters, can be created around the edges of parking lots to capture and treat stormwater runoff before releasing it to the watershed or storm sewer.

Permeable pavement

This section is an excerpt from Permeable paving.[edit]
 
Permeable paving demonstration
 
Stone paving in Santarém, Portugal

Permeable paving surfaces are made of either a porous material that enables stormwater to flow through it or nonporous blocks spaced so that water can flow between the gaps. Permeable paving can also include a variety of surfacing techniques for roads, parking lots, and pedestrian walkways. Permeable pavement surfaces may be composed of; pervious concrete, porous asphalt, paving stones, or interlocking pavers.[22] Unlike traditional impervious paving materials such as concrete and asphalt, permeable paving systems allow stormwater to percolate and infiltrate through the pavement and into the aggregate layers and/or soil below. In addition to reducing surface runoff, permeable paving systems can trap suspended solids, thereby filtering pollutants from stormwater.[23]

Permeable pavement is commonly used on roads, paths and parking lots subject to light vehicular traffic, such as cycle-paths, service or emergency access lanes, road and airport shoulders, and residential sidewalks and driveways.

Wetlands

Artificial wetlands can be constructed in areas that see large volumes of storm water surges or runoff. Built to replicate shallow marshes, wetlands as BMPs gather and filter water at scales larger than bioswales or rain gardens. Unlike bioswales, artificial wetlands are designed to replicate natural wetlands processes as opposed to having an engineered mechanism within the artificial wetland. Because of this, the ecology of the wetland (soil components, water, vegetation, microbes, sunlight processes, etc.) becomes the primary system to remove pollutants.[24] Water in an artificial wetland tends to be filtered slowly in comparison to systems with mechanized or explicitly engineered components.

Wetlands can be used to concentrate large volumes of runoff from urban areas and neighborhoods. In 2012, the South Los Angeles Wetlands Park was constructed in a densely populated inner-city district as a renovation for a former LA Metro bus yard.[25] The park is designed to capture runoff from surrounding surfaces as well as storm water overflow from the city's current drainage system.[26]

 
Trounce Pond in Saskatoon, Canada, serves as a storm water detention basin within the local drainage system.

Detention basins

This section is an excerpt from Retention basin.[edit]
 
Trounce Pond, a retention basin landscaped with natural grassland plants, in Saskatoon, Saskatchewan, Canada
 
The Corporate Park retention basin in Stafford, Texas, United States
 
Retention basin in Pinnau, Schleswig-Holstein, Germany

A retention basin, sometimes called a retention pond, wet detention basin, or storm water management pond (SWMP), is an artificial pond with vegetation around the perimeter and a permanent pool of water in its design.[27][28][29] It is used to manage stormwater runoff, for protection against flooding, for erosion control, and to serve as an artificial wetland and improve the water quality in adjacent bodies of water.

It is distinguished from a detention basin, sometimes called a "dry pond", which temporarily stores water after a storm, but eventually empties out at a controlled rate to a downstream water body. It also differs from an infiltration basin which is designed to direct stormwater to groundwater through permeable soils.

Wet ponds are frequently used for water quality improvement, groundwater recharge, flood protection, aesthetic improvement, or any combination of these. Sometimes they act as a replacement for the natural absorption of a forest or other natural process that was lost when an area is developed. As such, these structures are designed to blend into neighborhoods and viewed as an amenity.[30]

In urban areas, impervious surfaces (roofs, roads) reduce the time spent by rainfall before entering into the stormwater drainage system. If left unchecked, this will cause widespread flooding downstream. The function of a stormwater pond is to contain this surge and release it slowly. This slow release mitigates the size and intensity of storm-induced flooding on downstream receiving waters. Stormwater ponds also collect suspended sediments, which are often found in high concentrations in stormwater water due to upstream construction and sand applications to roadways.

Green roofs

This section is an excerpt from Green roof.[edit]
 
Green roof at the British Horse Society headquarters

A green roof or living roof is a roof of a building that is partially or completely covered with vegetation and a growing medium, planted over a waterproofing membrane. It may also include additional layers such as a root barrier and drainage and irrigation systems.[31] Container gardens on roofs, where plants are maintained in pots, are not generally considered to be true green roofs, although this is debated. Rooftop ponds are another form of green roofs which are used to treat greywater.[32] Vegetation, soil, drainage layer, roof barrier and irrigation system constitute green roof.[33]

Green roofs serve several purposes for a building, such as absorbing rainwater, providing insulation, creating a habitat for wildlife, increasing benevolence,[34] and decreasing stress of the people around the roof by providing a more aesthetically pleasing landscape, and helping to lower urban air temperatures and mitigate the heat island effect.[35] Green roofs are suitable for retrofit or redevelopment projects as well as new buildings and can be installed on small garages or larger industrial, commercial and municipal buildings.[31] They effectively use the natural functions of plants to filter water and treat air in urban and suburban landscapes.[36] There are two types of green roof: intensive roofs, which are thicker, with a minimum depth of 12.8 cm (5+116 in), and can support a wider variety of plants but are heavier and require more maintenance, and extensive roofs, which are shallow, ranging in depth from 2 to 12.7 cm (1316 to 5 in), lighter than intensive green roofs, and require minimal maintenance.[37]

The term green roof may also be used to indicate roofs that use some form of green technology, such as a cool roof, a roof with solar thermal collectors or photovoltaic panels. Green roofs are also referred to as eco-roofs, oikosteges, vegetated roofs, living roofs, greenroofs and VCPH[38] (Horizontal Vegetated Complex Partitions)

Rain gardens edit

Rain gardens are a form of stormwater management using water capture. Rain gardens are shallow depressed areas in the landscape, planted with shrubs and plants that are used to collect rainwater from roofs or pavement and allows for the stormwater to slowly infiltrate into the ground .[39] Rain gardens mimic natural landscape functions by capturing stormwater, filtering out pollutants, and recharging groundwater.[40] A study done in 2008 explains how rain gardens and stormwater planters are easy to incorporate into urban areas where they will improve the streets by minimizing the effects of drought and helping out with stormwater runoff. Stormwater planters can easily fit between other street landscapes and ideal in areas where spacing is tight.[41]

Downspout disconnection edit

Downspout disconnection is a form of green infrastructure that separates roof downspouts from the sewer system and redirects roof water runoff into permeable surfaces.[14] It can be used for storing stormwater or allowing the water to penetrate the ground. Downspout disconnection is especially beneficial in cities with combined sewer systems. With high volumes of rain, downspouts on buildings can send 12 gallons of water a minute into the sewer system, which increases the risk of basement backups and sewer overflows.[42]

Benefits for stormwater management edit

Green infrastructure keeps waterways clean and healthy in two primary ways; water retention and water quality. Different green infrastructure strategies prevents runoff by capturing the rain where it lies, allowing it to filter into the ground to recharge groundwater, return to the atmosphere through evapotranspiration, or be reused for another purpose like landscaping.[43] Water quality is also improved by decreasing the amount of stormwater that reaches other waterways and removing contaminants. Vegetation and soil help capture and remove pollutants from stormwater in many ways like adsorption, filtration, and plant uptake.[44] These processes break down or capture many of the common pollutants found in runoff.

Reduced flooding edit

With climate change intensifying, heavy storms are becoming more frequent and so is the increasing risk of flooding and sewer system overflows. According to the EPA, the average size of a 100-year floodplain is likely to increase by 45% in the next ten years.[45] Another growing problem is urban flooding being caused by too much rain on impervious surfaces, urban floods can destroy neighborhoods.[46] They particularly affect minority and low-income neighborhoods and can leave behind health problems like asthma and illness caused by mold. Green infrastructure reduces flood risks and bolsters the climate resiliency of communities by keeping rain out of sewers and waterways, capturing it where it falls.[47][48]

Increased water supply edit

More than half of the rain that falls in urban areas covered mostly by impervious surfaces ends up as runoff.[49] Green infrastructure practices reduce runoff by capturing stormwater and allowing it to recharge groundwater supplies or be harvested for purposes like landscaping. Green infrastructure promotes rainfall conservation through the use of capture methods and infiltration techniques, for instance bioswales. As much as 75 percent of the rainfall that lands on a rooftop can be captured and used for other purposes.[50]

Heat management edit

A city with miles of dark hot pavement absorbs and radiates heat into the surrounding atmosphere at a greater rate than a natural landscapes do.[51] This is urban heat island effect causing an increase in air temperatures. The EPA estimates that the average air temperature of a city with one million people or more can be 1.8 to 5.4 °F (1.0 to 3.0 °C) warmer than surrounding areas.[51] Higher temperatures reduce air quality by increasing smog. In Los Angeles, a 1 degree temperature increase makes the air roughly 3 percent more smog.[52] Green roofs and other forms of green infrastructure help improve air quality and reduce smog through their use of vegetation. Plants not only provide shade for cooling, but also absorb pollutants like carbon dioxide and help reduce air temperatures through evaporation and evapotranspiration.[53]

Health benefits edit

By improving water quality, reducing air temperatures and pollution, green infrastructure provides many public health benefits. Cooler and cleaner air can help reduce heat related illnesses like exhaustion and heatstroke, as well as respiratory problems like asthma.[54] Cleaner and healthier waterways also means less illness from contaminated waters and seafood. Greener areas also promote physical activity and can boost mental health.[54]

Reduced costs edit

Green infrastructure is often cheaper than more conventional water management strategies. Philadelphia found that its new green infrastructure plan will cost $1.2 billion over 25 years, compared with the $6 billion a gray infrastructure would have cost.[55] The expenses for implementing green infrastructure are often smaller, planting a rain garden to deal with drainage costs less than digging tunnels and installing pipes. But even when it is not cheaper, green infrastructure still has a good long-term effect. A green roof lasts twice as long as a regular roof, and low maintenance costs of permeable pavement can make for a good long-term investment.[56] The Iowa town of West Union determined it could save $2.5 million over the lifespan of a single parking lot by using permeable pavement instead of traditional asphalt.[57] Green infrastructure also improves the quality of water drawn from rivers and lakes for drinking, which reduces the costs associated with purification and treatment, in some cases by more than 25 percent.[58] And green roofs can reduce heating and cooling costs, leading to energy savings of as much as 15 percent.[59]

See also edit

References edit

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External links edit

  • SUDS solutions from the British Geological Survey
  • International Best Management Practices Database – Detailed data sets & summaries on performance of Urban BMPs
  • Portland Guide to Sustainable Stormwater – City of Portland, Oregon

December 20, 2023
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This article includes a list of general references but it lacks sufficient corresponding inline citations Please help to improve this article by introducing more precise citations May 2019 Learn how and when to remove this template message Sustainable drainage systems also known as SuDS 1 SUDS 2 3 or sustainable urban drainage systems 4 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 5 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 6 Retention ponds such as this one in Dunfermline Scotland are considered components of a sustainable drainage system SuDS have become popular in recent decades as understanding of how urban development affects natural environments as well as concern for climate change and sustainability have increased SuDS often use built components that mimic natural features in order to integrate urban drainage systems into the natural drainage systems or a site as efficiently and quickly as possible SUDS infrastructure has become a large part of the Blue Green Cities demonstration project in Newcastle upon Tyne 7 Contents 1 History of drainage systems 2 Background 3 Example features 3 1 Rain gardens 3 2 Downspout disconnection 4 Benefits for stormwater management 4 1 Reduced flooding 4 2 Increased water supply 4 3 Heat management 4 4 Health benefits 4 5 Reduced costs 5 See also 6 References 7 External linksHistory of drainage systems editDrainage systems have been found in ancient cities over 5 000 years old including Minoan Indus Persian and Mesopotamian civilizations 8 These drainage systems focused mostly on reducing nuisances from localized flooding and waste water Rudimentary systems made from brick or stone channels constituted the extent of urban drainage technologies for centuries Cities in Ancient Rome also employed drainage systems to protect low lying areas from excess rainfall When builders began constructing aqueducts to import fresh water into cities urban drainage systems became integrated into water supply infrastructure for the first time as a unified urban water cycle 9 nbsp Bazzalgette combined sewer system being built in 1860 LondonModern drainage systems did not appear until the 19th century in Western Europe although most of these systems were primarily built to deal with sewage issues rising from rapid urbanization One such example is that of the London sewerage system which was constructed to combat massive contamination of the River Thames At the time the River Thames was the primary component of London s drainage system with human waste concentrating in the waters adjacent to the densely populated urban center As a result several epidemics plagued London s residents and even members of Parliament including events known as the 1854 Broad Street cholera outbreak and the Great Stink of 1858 10 The concern for public health and quality of life launched several initiatives which ultimately led to the creation of London s modern sewerage system designed by Joseph Bazalgette 11 This new system explicitly aimed to ensure waste water was redirected as far away from water supply sources as possible in order to reduce the threat of waterborne pathogens Since then most urban drainage systems have aimed for similar goals of preventing public health crises Within past decades as climate change and urban flooding have become increasingly urgent challenges drainage systems designed specifically for environmental sustainability have become more popular in both academia and practice The first sustainable drainage system to utilize a full management train including source control in the UK was the Oxford services motorway station designed by SuDS specialists Robert Bray Associates 12 Originally the term SUDS described the UK approach to sustainable urban drainage systems These developments may not necessarily be in urban areas and thus the urban part of SuDS is now usually dropped to reduce confusion Other countries have similar approaches in place using a different terminology such as best management practice BMP and low impact development in the United States 13 water sensitive urban design WSUD in Australia 14 low impact urban design and development LIUDD in New Zealand 15 and comprehensive urban river basin management in Japan 14 The National Research Council s definitive report on urban stormwater management described that urban drainage systems began in the United States after World War II These structures were based on simple catch basins and pipes to transfer the water outside of the cities 16 Urban stormwater management started to evolve more in the 1970s when landscape architects focused more on low impact development and began using practices such as infiltration channels 16 Parallel to this time scientists started becoming concerned with other stormwater hazards surrounding pollution Studies such as the Nationwide Urban Runoff Program showed that urban runoff contained pollutants like heavy metals sediments and pathogens all of which water can pick up as it flows off of impermeable surfaces 17 It was at the beginning of the 21st century where stormwater infrastructure to allow runoff to infiltrate close to the source became popular This was around the same time that the term green infrastructure was coined 18 Background editTraditional urban drainage systems are limited by various factors including volume capacity damage or blockage from debris and contamination of drinking water Many of these issues are addressed by SuDS systems by bypassing traditional drainage systems altogether and returning rainwater to natural water sources or streams as soon as possible Increasing urbanisation has caused problems with increased flash flooding after sudden rain As areas of vegetation are replaced by concrete asphalt or roofed structures leading to impervious surfaces the area loses its ability to absorb rainwater This rain is instead directed into surface water drainage systems often overloading them and causing floods The goal of all sustainable drainage systems is to use rainfall to recharge the water sources of a given site These water sources are often underlying the water table nearby streams lakes or other similar freshwater sources For example if a site is above an unconsolidated aquifer then SuDS will aim to direct all rain that falls on the surface layer into the underground aquifer as quickly as possible To accomplish this SuDS use various forms of permeable layers to ensure the water is not captured or redirected to another location Often these layers include soil and vegetation though they can also be artificial materials The paradigm of SuDS solutions should be that of a system that is easy to manage requiring little or no energy input except from environmental sources such as sunlight etc resilient to use and being environmentally as well as aesthetically attractive Examples of this type of system are basins shallow landscape depressions that are dry most of the time when it is not raining rain gardens shallow landscape depressions with shrub or herbaceous planting swales shallow normally dry wide based ditches filter drains gravel filled trench drain bioretention basins shallow depressions with gravel and or sand filtration layers beneath the growing medium reed beds and other wetland habitats that collect store and filter dirty water along with providing a habitat for wildlife A common misconception of SuDS is that they reduce flooding on the development site In fact the SuDS is designed to reduce the impact that the surface water drainage system of one site has on other sites For instance sewer flooding is a problem in many places Paving or building over land can result in flash flooding This happens when flows entering a sewer exceed its capacity and it overflows The SuDS system aims to minimise or eliminate discharges from the site thus reducing the impact the idea being that if all development sites incorporated SuDS then urban sewer flooding would be less of a problem Unlike traditional urban stormwater drainage systems SuDS can also help to protect and enhance ground water quality Example features editBecause SuDS describe a collection of systems with similar components or goals there is a large crossover between SuDS and other terminologies dealing with sustainable urban development 19 The following are examples generally accepted as components in a SuDS system nbsp Roadside bioswale designed to filter storm water runoff from street surfacesBioswales This section is an excerpt from Bioswale edit nbsp Runoff from the street flows directly into an adjacent bioswaleBioswales are channels designed to concentrate and convey stormwater runoff while removing debris and pollution Bioswales can also be beneficial in recharging groundwater Bioswales are typically vegetated mulched or xeriscaped 20 They consist of a swaled drainage course with gently sloped sides less than 6 21 19 Bioswale design is intended to safely maximize the time water spends in the swale which aids the collection and removal of pollutants silt and debris Depending on the site topography the bioswale channel may be straight or meander Check dams are also commonly added along the bioswale to increase stormwater infiltration A bioswale s make up can be influenced by many different variables including climate rainfall patterns site size budget and vegetation suitability It is important to maintain bioswales to ensure the best possible efficiency and effectiveness in removal of pollutants from stormwater runoff Planning for maintenance is an important step which can include the introduction of filters or large rocks to prevent clogging Annual maintenance through soil testing visual inspection and mechanical testing is also crucial to the health of a bioswale Bioswales are commonly applied along streets and around parking lots where substantial automotive pollution settles on the pavement and is flushed by the first instance of rain known as the first flush Bioswales or other types of biofilters can be created around the edges of parking lots to capture and treat stormwater runoff before releasing it to the watershed or storm sewer Permeable pavement This section is an excerpt from Permeable paving edit This article possibly contains original research Please improve it by verifying the claims made and adding inline citations Statements consisting only of original research should be removed June 2010 Learn how and when to remove this template message nbsp Permeable paving demonstration nbsp Stone paving in Santarem PortugalPermeable paving surfaces are made of either a porous material that enables stormwater to flow through it or nonporous blocks spaced so that water can flow between the gaps Permeable paving can also include a variety of surfacing techniques for roads parking lots and pedestrian walkways Permeable pavement surfaces may be composed of pervious concrete porous asphalt paving stones or interlocking pavers 22 Unlike traditional impervious paving materials such as concrete and asphalt permeable paving systems allow stormwater to percolate and infiltrate through the pavement and into the aggregate layers and or soil below In addition to reducing surface runoff permeable paving systems can trap suspended solids thereby filtering pollutants from stormwater 23 Permeable pavement is commonly used on roads paths and parking lots subject to light vehicular traffic such as cycle paths service or emergency access lanes road and airport shoulders and residential sidewalks and driveways WetlandsArtificial wetlands can be constructed in areas that see large volumes of storm water surges or runoff Built to replicate shallow marshes wetlands as BMPs gather and filter water at scales larger than bioswales or rain gardens Unlike bioswales artificial wetlands are designed to replicate natural wetlands processes as opposed to having an engineered mechanism within the artificial wetland Because of this the ecology of the wetland soil components water vegetation microbes sunlight processes etc becomes the primary system to remove pollutants 24 Water in an artificial wetland tends to be filtered slowly in comparison to systems with mechanized or explicitly engineered components Wetlands can be used to concentrate large volumes of runoff from urban areas and neighborhoods In 2012 the South Los Angeles Wetlands Park was constructed in a densely populated inner city district as a renovation for a former LA Metro bus yard 25 The park is designed to capture runoff from surrounding surfaces as well as storm water overflow from the city s current drainage system 26 nbsp Trounce Pond in Saskatoon Canada serves as a storm water detention basin within the local drainage system Detention basins This section is an excerpt from Retention basin edit nbsp Trounce Pond a retention basin landscaped with natural grassland plants in Saskatoon Saskatchewan Canada nbsp The Corporate Park retention basin in Stafford Texas United States nbsp Retention basin in Pinnau Schleswig Holstein GermanyA retention basin sometimes called a retention pond wet detention basin or storm water management pond SWMP is an artificial pond with vegetation around the perimeter and a permanent pool of water in its design 27 28 29 It is used to manage stormwater runoff for protection against flooding for erosion control and to serve as an artificial wetland and improve the water quality in adjacent bodies of water It is distinguished from a detention basin sometimes called a dry pond which temporarily stores water after a storm but eventually empties out at a controlled rate to a downstream water body It also differs from an infiltration basin which is designed to direct stormwater to groundwater through permeable soils Wet ponds are frequently used for water quality improvement groundwater recharge flood protection aesthetic improvement or any combination of these Sometimes they act as a replacement for the natural absorption of a forest or other natural process that was lost when an area is developed As such these structures are designed to blend into neighborhoods and viewed as an amenity 30 In urban areas impervious surfaces roofs roads reduce the time spent by rainfall before entering into the stormwater drainage system If left unchecked this will cause widespread flooding downstream The function of a stormwater pond is to contain this surge and release it slowly This slow release mitigates the size and intensity of storm induced flooding on downstream receiving waters Stormwater ponds also collect suspended sediments which are often found in high concentrations in stormwater water due to upstream construction and sand applications to roadways Green roofs This section is an excerpt from Green roof edit nbsp Green roof at the British Horse Society headquartersA green roof or living roof is a roof of a building that is partially or completely covered with vegetation and a growing medium planted over a waterproofing membrane It may also include additional layers such as a root barrier and drainage and irrigation systems 31 Container gardens on roofs where plants are maintained in pots are not generally considered to be true green roofs although this is debated Rooftop ponds are another form of green roofs which are used to treat greywater 32 Vegetation soil drainage layer roof barrier and irrigation system constitute green roof 33 Green roofs serve several purposes for a building such as absorbing rainwater providing insulation creating a habitat for wildlife increasing benevolence 34 and decreasing stress of the people around the roof by providing a more aesthetically pleasing landscape and helping to lower urban air temperatures and mitigate the heat island effect 35 Green roofs are suitable for retrofit or redevelopment projects as well as new buildings and can be installed on small garages or larger industrial commercial and municipal buildings 31 They effectively use the natural functions of plants to filter water and treat air in urban and suburban landscapes 36 There are two types of green roof intensive roofs which are thicker with a minimum depth of 12 8 cm 5 1 16 in and can support a wider variety of plants but are heavier and require more maintenance and extensive roofs which are shallow ranging in depth from 2 to 12 7 cm 13 16 to 5 in lighter than intensive green roofs and require minimal maintenance 37 The term green roof may also be used to indicate roofs that use some form of green technology such as a cool roof a roof with solar thermal collectors or photovoltaic panels Green roofs are also referred to as eco roofs oikosteges vegetated roofs living roofs greenroofs and VCPH 38 Horizontal Vegetated Complex Partitions Rain gardens edit Rain gardens are a form of stormwater management using water capture Rain gardens are shallow depressed areas in the landscape planted with shrubs and plants that are used to collect rainwater from roofs or pavement and allows for the stormwater to slowly infiltrate into the ground 39 Rain gardens mimic natural landscape functions by capturing stormwater filtering out pollutants and recharging groundwater 40 A study done in 2008 explains how rain gardens and stormwater planters are easy to incorporate into urban areas where they will improve the streets by minimizing the effects of drought and helping out with stormwater runoff Stormwater planters can easily fit between other street landscapes and ideal in areas where spacing is tight 41 Downspout disconnection edit Downspout disconnection is a form of green infrastructure that separates roof downspouts from the sewer system and redirects roof water runoff into permeable surfaces 14 It can be used for storing stormwater or allowing the water to penetrate the ground Downspout disconnection is especially beneficial in cities with combined sewer systems With high volumes of rain downspouts on buildings can send 12 gallons of water a minute into the sewer system which increases the risk of basement backups and sewer overflows 42 Benefits for stormwater management editGreen infrastructure keeps waterways clean and healthy in two primary ways water retention and water quality Different green infrastructure strategies prevents runoff by capturing the rain where it lies allowing it to filter into the ground to recharge groundwater return to the atmosphere through evapotranspiration or be reused for another purpose like landscaping 43 Water quality is also improved by decreasing the amount of stormwater that reaches other waterways and removing contaminants Vegetation and soil help capture and remove pollutants from stormwater in many ways like adsorption filtration and plant uptake 44 These processes break down or capture many of the common pollutants found in runoff Reduced flooding edit With climate change intensifying heavy storms are becoming more frequent and so is the increasing risk of flooding and sewer system overflows According to the EPA the average size of a 100 year floodplain is likely to increase by 45 in the next ten years 45 Another growing problem is urban flooding being caused by too much rain on impervious surfaces urban floods can destroy neighborhoods 46 They particularly affect minority and low income neighborhoods and can leave behind health problems like asthma and illness caused by mold Green infrastructure reduces flood risks and bolsters the climate resiliency of communities by keeping rain out of sewers and waterways capturing it where it falls 47 48 Increased water supply edit More than half of the rain that falls in urban areas covered mostly by impervious surfaces ends up as runoff 49 Green infrastructure practices reduce runoff by capturing stormwater and allowing it to recharge groundwater supplies or be harvested for purposes like landscaping Green infrastructure promotes rainfall conservation through the use of capture methods and infiltration techniques for instance bioswales As much as 75 percent of the rainfall that lands on a rooftop can be captured and used for other purposes 50 Heat management edit A city with miles of dark hot pavement absorbs and radiates heat into the surrounding atmosphere at a greater rate than a natural landscapes do 51 This is urban heat island effect causing an increase in air temperatures The EPA estimates that the average air temperature of a city with one million people or more can be 1 8 to 5 4 F 1 0 to 3 0 C warmer than surrounding areas 51 Higher temperatures reduce air quality by increasing smog In Los Angeles a 1 degree temperature increase makes the air roughly 3 percent more smog 52 Green roofs and other forms of green infrastructure help improve air quality and reduce smog through their use of vegetation Plants not only provide shade for cooling but also absorb pollutants like carbon dioxide and help reduce air temperatures through evaporation and evapotranspiration 53 Health benefits edit By improving water quality reducing air temperatures and pollution green infrastructure provides many public health benefits Cooler and cleaner air can help reduce heat related illnesses like exhaustion and heatstroke as well as respiratory problems like asthma 54 Cleaner and healthier waterways also means less illness from contaminated waters and seafood Greener areas also promote physical activity and can boost mental health 54 Reduced costs edit Green infrastructure is often cheaper than more conventional water management strategies Philadelphia found that its new green infrastructure plan will cost 1 2 billion over 25 years compared with the 6 billion a gray infrastructure would have cost 55 The expenses for implementing green infrastructure are often smaller planting a rain garden to deal with drainage costs less than digging tunnels and installing pipes But even when it is not cheaper green infrastructure still has a good long term effect A green roof lasts twice as long as a regular roof and low maintenance costs of permeable pavement can make for a good long term investment 56 The Iowa town of West Union determined it could save 2 5 million over the lifespan of a single parking lot by using permeable pavement instead of traditional asphalt 57 Green infrastructure also improves the quality of water drawn from rivers and lakes for drinking which reduces the costs associated with purification and treatment in some cases by more than 25 percent 58 And green roofs can reduce heating and cooling costs leading to energy savings of as much as 15 percent 59 See also editAquifer storage and recovery Blue roof Detention basin Drainage system disambiguation French drain Low impact development U S and Canada Rain garden Resin bound paving Retention basin Sponge city Stream restoration Sustainable city Urban runoff Tree box filter Water sensitive urban designReferences edit Sustainable Drainage System SuDs for Stormwater Management A Technological and Policy Intervention to Combat Diffuse Pollution Sharma D 2008 CIRIA guide to SUDS Ciria org Retrieved January 21 2014 Planning and Sustainable Urban Drainage Systems Planning Advice Note 61 Scottish Government Planning Services July 27 2001 Archived from the original on February 18 2015 Sustainable Urban Drainage Systems www sustainable urban drainage systems co uk Retrieved November 15 2020 CIRIA SuDS Manual Document reference CIRIA C753 2015 Hoang L 2016 System interactions of stormwater management using sustainable urban drainage systems and green infrastructure Urban Water Journal 13 7 739 758 doi 10 1080 1573062X 2015 1036083 O Donnell E C Lamond J E Thorne C R 2017 Recognising barriers to implementation of Blue Green Infrastructure a Newcastle case study Urban Water Journal 14 9 964 971 doi 10 1080 1573062X 2017 1279190 ISSN 1573 062X Angelakis Andreas De Feo Giovanni Laureano Pietro Zourou Anastasia July 8 2013 Minoan and Etruscan Hydro Technologies Water 5 3 972 987 doi 10 3390 w5030972 ISSN 2073 4441 Burian Steven J Edwards Findlay G 2002 Historical Perspectives of Urban Drainage Global Solutions for Urban Drainage Proceedings 1 16 doi 10 1061 40644 2002 284 ISBN 978 0 7844 0644 1 Re Smelling London s Great Stink Of 1858 All That s Interesting December 7 2017 Retrieved April 21 2019 BBC History Joseph Bazalgette www bbc co uk Retrieved April 21 2019 CIRIA Oxford Motorway Services Case Study Reducing Stormwater Costs through Low Impact Development Strategies and Practices Fact Sheet Washington D C U S Environmental Protection Agency EPA December 2007 EPA 841 F 07 006A a b c Chen Chi Feng Sheng Ming Yang Chang Chia Ling Kang Shyh Fang Lin Jen Yang 2014 Application of the SUSTAIN Model to a Watershed Scale Case for Water Quality Management Water 6 12 3575 3589 doi 10 3390 w6123575 ISSN 2073 4441 Eckart Kyle McPhee Zach Bolisetti Tirupati 2017 Performance and implementation of low impact development A review Science of the Total Environment 607 608 413 432 Bibcode 2017ScTEn 607 413E doi 10 1016 j scitotenv 2017 06 254 PMID 28704668 a b National Research Council 2009 Urban Stormwater Management in the United States Washington DC The National Academies Press doi 10 17226 12465 Environmental Protection Agency 1983 Results of the Nationwide Urban Runoff Program Vol 1 Retrieved from https www3 epa gov npdes pubs sw nurp vol 1 finalreport pdf Metzger J P Loyola R Diniz Filho J A F amp Pillar V D 2017 New perspectives in ecology and conservation Perspectives in Ecology and Conservation 15 1 32 35 doi 10 1016 j pecon 2017 02 001 Campos Priscila Celebrini de Oliveira Paz Taina da Silva Rocha Lenz Leticia Qiu Yangzi Alves Camila Nascimento Simoni Ana Paula Roem Amorim Jose Carlos Cesar Lima Gilson Brito Alves Rangel Maysa Pontes Paz Igor 2020 Multi Criteria Decision Method for Sustainable Watercourse Management in Urban Areas Sustainability 12 16 6493 doi 10 3390 su12166493 Stormwater Best Management Practice Grassed Swales PDF Washington D C U S Environmental Protection Agency EPA December 2021 p 3 EPA 832 F 21 031P Loechl Paul M et al 2003 Design Schematics for a Sustainable Parking Lot PDF Champaign IL US Army Corps of Engineers Research and Development Center Archived from the original PDF on June 2 2010 Construction Engineering Research Laboratory Document no ERDC CERL TR 03 12 US EPA OW September 30 2015 What is Green Infrastructure US EPA Retrieved August 16 2019 Interlocking Concrete Pavement Institute http www icpi org sustainable Constructed wetlands Kandasamy Jaya Vigneswaran Saravanamuthu 1952 New York Nova Science Publishers 2008 ISBN 9781616680817 OCLC 847617134 a href Template Cite book html title Template Cite book cite book a CS1 maint others link Walker Alissa February 1 2023 L A s Green Alley Experiments Are Working Curbed Retrieved February 3 2023 Fuentes Ed February 14 2012 Innovative Wetlands Park Opens in South Los Angeles KCET Retrieved April 21 2019 Water Environment Federation Alexandria VA and American Society of Civil Engineers Reston VA Urban Runoff Quality Management WEF Manual of Practice No 23 ASCE Manual and Report on Engineering Practice No 87 1998 ISBN 1 57278 039 8 Chapter 5 U S Environmental Protection Agency Washington D C Preliminary Data Summary of Urban Storm Water Best Management Practices Chapter 5 August 1999 Document No EPA 821 R 99 012 University of Florida Institute of Food and Agricultural Sciences If you build it they will come Frogs flourish in humanmade ponds ScienceDaily ScienceDaily 27 August 2015 lt www sciencedaily com releases 2015 08 150827154644 htm gt Mississippi State University College of Engineering Stormwater Retention Basins Chapter 4 Best Management Practices a b Rodriguez Droguett Barbara 2011 Sustainability assessment of green infrastructure practices for stormwater management A comparative emergy analysis Thesis ProQuest 900864997 Ozyavuz Murat B Karakaya and D G Ertin The Effects of Green Roofs on Urban Ecosystems GreenAge Symposium 2015 EPA 2017 Green Roofs U S EPA Available from http www epa gov heatisland strategies greenroofs html Benefits of Green Roofs www greenroof hrt msu edu Archived from the original on July 4 2018 Retrieved November 1 2018 Vandermeulen Valerie Verspecht Ann Vermeire Bert Van Huylenbroeck Guido Gellynck Xavier November 2011 The use of economic valuation to create public support for green infrastructure investments in urban areas Landscape and Urban Planning 103 2 198 206 doi 10 1016 j landurbplan 2011 07 010 System Overview Planted Roof GSA Sustainable Facilities Tool sftool gov Volder Astrid Dvorak Bruce February 2014 Event size substrate water content and vegetation affect storm water retention efficiency of an un irrigated extensive green roof system in Central Texas Sustainable Cities and Society 10 59 64 doi 10 1016 j scs 2013 05 005 Aurelien P JEAN Archived from the original on August 24 2011 Retrieved May 19 2011 Environmental Protection Agency n d Different Shades of Green Retrieved from https www epa gov sites production files 2016 10 documents green infrastructure brochure final pdf Green Infrastructure Rain Gardens thewatershed org June 11 2019 Retrieved May 11 2020 Dunnett N amp Clayden A 2008 Rain Gardens Managing Water Sustainably in the Garden and Designed Landscape Portland Timber Why You Should Disconnect Your Downspout www mmsd com October 19 2016 Retrieved May 11 2020 inspsw May 28 2009 Stormwater 101 Detention and Retention Basins Sustainable Stormwater Management Retrieved May 11 2020 Environmental Protection Agency 1999 Stormwater Technology Fact Sheet Retrieved from https nepis epa gov Exe ZyPDF cgi 200044BE PDF Dockey 200044BE PDF US EPA OW October 1 2015 Manage Flood Risk US EPA Retrieved May 11 2020 January 15 Weber 2019 Anna What Is Urban Flooding NRDC Retrieved May 11 2020 a href Template Cite web html title Template Cite web cite web a CS1 maint numeric names authors list link Pauleit S Fryd O Backhaus A Jensen M B 2013 Green Infrastructure and Climate Change In Loftness V Haase D eds Sustainable Built Environments Springer New York NY Pallathadka Arun Sauer Jason Chang Heejun Grimm Nancy 2022 Urban flood risk and green infrastructure Who is exposed to risk and who benefits from investment A case study of three US Cities Landscape and Urban Planning 223 104417 doi 10 1016 j landurbplan 2022 104417 S2CID 247896059 Using Nature to Tackle Water Infrastructure Challenges Frontiers of Green Infrastructure Research at Stanford Water in the West waterinthewest stanford edu Retrieved May 11 2020 A Clear Blue Future How Greening California Cities Can Address Water Resources and Climate Challenges in the 21st Century NRDC Retrieved May 11 2020 a b US EPA OAR February 28 2014 Heat Island Effect US EPA Retrieved May 11 2020 Robinson Elmer June 1952 Some Air Pollution Aspects of the Los Angeles Temperature Inversion Bulletin of the American Meteorological Society 33 6 247 250 Bibcode 1952BAMS 33 247R doi 10 1175 1520 0477 33 6 247 ISSN 0003 0007 Tallis Matthew amp Amorim Jorge amp Calfapietra Carlo amp Freer Smith Peter amp Grimmond Christine amp Kotthaus Simone amp Lemes de Oliveira Fabiano amp Miranda Ana amp Toscano Piero 2015 The impacts of green infrastructure on air quality and temperature 10 4337 9781783474004 00008 a b Hill Jason Polasky Stephen Nelson Erik Tilman David Huo Hong Ludwig Lindsay Neumann James Zheng Haochi Bonta Diego February 2 2009 Climate change and health costs of air emissions from biofuels and gasoline Proceedings of the National Academy of Sciences 106 6 2077 2082 Bibcode 2009PNAS 106 2077H doi 10 1073 pnas 0812835106 ISSN 0027 8424 PMC 2634804 PMID 19188587 Green Jared December 18 2013 The New Philadelphia Story Is About Green Infrastructure THE DIRT Retrieved May 11 2020 Mell Ian C Henneberry John Hehl Lange Sigrid Keskin Berna August 2016 To green or not to green Establishing the economic value of green infrastructure investments in The Wicker Sheffield PDF Urban Forestry amp Urban Greening 18 257 267 doi 10 1016 j ufug 2016 06 015 ISSN 1618 8667 Havel J 2015 Sustainable Stormwater Treatment in Iowa City Iowa Initiative for Sustainable Communities Retrieved from https iisc uiowa edu sites iisc uiowa edu files project files stormwater management final report 0 pdf National Resources Defense Council 2011 After the Storm How Green Infrastructure Can Effectively Manage Stormwater Runoff from Roads and Highways After the Storm How Green Infrastructure Can Effectively Manage Stormwater Runoff from Roads and Highways a href Template Cite journal html title Template Cite journal cite journal a Check url value help Cite journal requires journal help The Green Edge How Commercial Property Investment in Green Infrastructure Creates Value NRDC Retrieved May 11 2020 External links editSUDS solutions from the British Geological Survey International Best Management Practices Database Detailed data sets amp summaries on performance of Urban BMPs Portland Guide to Sustainable Stormwater City of Portland Oregon Retrieved from https en wikipedia org w index php title Sustainable drainage system amp oldid 1182113178, wikipedia, wiki, book, books, library,

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