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[[File:picture of porous concrete 1.jpg|thumb|300px|alt=This photo illustrates an example of pervious concrete|<font size=2>This photo illustrates an example of pervious concrete.</font size>]]
 
[[File:picture of porous concrete 1.jpg|thumb|300px|alt=This photo illustrates an example of pervious concrete|<font size=2>This photo illustrates an example of pervious concrete.</font size>]]
  
Permeable pavements allow stormwater runoff to filter through surface voids into an underlying stone reservoir where it is temporarily stored and/or infiltrated. The most commonly used permeable pavement surfaces are pervious concrete, porous asphalt and permeable interlocking pavers. Permeable pavements have been used for commercial and residential sites to replace traditionally impervious surfaces. These include roads, parking lots, driveways, sidewalks, plazas and patios.
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Permeable pavements allow stormwater runoff to filter through surface voids into an underlying stone reservoir where it is temporarily stored and/or infiltrated. The most commonly used permeable pavement surfaces are pervious concrete, porous asphalt, and permeable interlocking concrete pavers (PICP). Permeable pavements have been used for areas with light traffic at commercial and residential sites to replace traditionally impervious surfaces such as low-speed roads, parking lots, driveways, sidewalks, plazas, and patios. Permeable pavement is not ideal for high traffic/high speed areas because it has lower load-bearing capacity than conventional pavement.
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While the designs vary, all permeable pavements have a similar structure, consisting of a surface pavement layer, an underlying stone aggregate reservoir layer, optional underdrains, and geotextile over uncompacted soil subgrade.
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From a hydrologic perspective, permeable pavement is typically designed to manage rainfall landing directly on the permeable pavement surface area.  Permeable pavement surface areas may accept runoff contributed by adjacent impervious areas such as driving lanes or rooftops. Runoff from adjacent vegetated areas is often discouraged because sediment in runoff from adjacent areas increases clogging of the permeable pavement, especially at the edges.  Additionally, the capacity of the underlying reservoir layer  limits the  contributing area. 
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{{alert|'''Sediment control from adjacent impervious or vegetated contributing areas is required to avoid clogging of the permeable pavement surface'''|alert-warning}}
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'''The individual articles comprising this section on permeable pavement may be viewed as a [[permeable pavement combined|single article]].'''
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[[File:Picture of porous asphalt 1.jpg|thumb|300px|alt=This photo illustrates an example of porous asphalt|<font size=2>This photo illustrates an example of porous asphalt</font size>]]
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[[File:Picture of permeable interlocking concrete pavement 1.jpg|thumb|300px|alt=This photo illustrates an example of permeable interlocking pavement|<font size=2>This photo illustrates an example of permeable interlocking pavement</font size>]]
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<div class="center" style="width:auto; margin-left:auto; margin-right:auto;"><font size=3><u>'''Porous pavement articles'''</u></font size>
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<div class="center">[[Overview for permeable pavement]]</div>
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<div class="center">[[Types of permeable pavement]]</div>
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<div class="center">[[Design criteria for permeable pavement]]</div>
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<div class="center">[[Construction specifications for permeable pavement]]</div>
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<!--<div class="center">[[Construction observations for permeable pavement]]</div>-->
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<div class="center">[[Assessing the performance of permeable pavement]]</div>
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<div class="center">[[Operation and maintenance of permeable pavement]]</div>
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<div class="center">[[Calculating credits for permeable pavement]]</div>
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<!--<div class="center">[[Cost-benefit considerations for permeable pavement]]</div>-->
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<div class="center">[[Additional considerations for permeable pavement]]</div>
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<div class="center">[[Links for permeable pavement]]</div>
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<div class="center">[[References for permeable pavement]]</div>
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<div class="center">[[Supporting material for permeable pavement]]</div>
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<div style="display:none">#[[Permeable pavement credits]]</div style>
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Several [[Fact sheets for permeable pavement|fact sheets]] for permeable pavement provide overview information and information on design, construction and maintenance, and volume and pollutant removal.
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[[category:BMP]]
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While the designs vary, all permeable pavements have a similar structure, consisting of a surface pavement layer, an underlying stone aggregate reservoir layer, optional underdrains, and geotextile over uncompacted soil subgrade.
 +
 
 +
 +
From a hydrologic perspective, permeable pavement is typically designed to manage rainfall landing directly on the permeable pavement surface area.  Permeable pavement surface areas may accept runoff contributed by adjacent impervious areas such as driving lanes or rooftops. Runoff from adjacent vegetated areas is often discouraged because sediment in runoff from adjacent areas increases clogging of the permeable pavement, especially at the edges.  Additionally, the capacity of the underlying reservoir layer  limits the  contributing area. 
  
While the designs vary, all permeable pavements have a similar structure, consisting of a surface pavement layer, an underlying stone aggregate reservoir layer, optional underdrains and geotextile over uncompacted soil subgrade.
 
  
From a hydrologic perspective, permeable pavement is typically designed to manage rainfall landing directly on the permeable pavement surface area. While designers and regulators often discourage it, permeable pavement surface areas may accept runoff contributed by adjacent impervious areas such as driving lanes or rooftops, or from adjacent vegetated areas. Sediment in runoff from adjacent areas increases clogging of the permeable pavement, especially at the edges. This should be considered when determining the size of the contributing drainage area. Additionally, the capacity of the underlying reservoir layer will limit the size of the contributing area.
 
  
 
{{alert|'''Sediment control from adjacent impervious or vegetated contributing areas is required to avoid clogging of the permeable pavement surface'''|alert-warning}}
 
{{alert|'''Sediment control from adjacent impervious or vegetated contributing areas is required to avoid clogging of the permeable pavement surface'''|alert-warning}}

Revision as of 17:27, 1 February 2013

This site is currently undergoing revision. For more information, open this link.
The anticipated construction period for this page is January through March, 2013
This site is currently undergoing final review. For more information, open this link.
The anticipated review period for this page is January through March, 2013
This photo illustrates an example of pervious concrete
This photo illustrates an example of pervious concrete.

Permeable pavements allow stormwater runoff to filter through surface voids into an underlying stone reservoir where it is temporarily stored and/or infiltrated. The most commonly used permeable pavement surfaces are pervious concrete, porous asphalt, and permeable interlocking concrete pavers (PICP). Permeable pavements have been used for areas with light traffic at commercial and residential sites to replace traditionally impervious surfaces such as low-speed roads, parking lots, driveways, sidewalks, plazas, and patios. Permeable pavement is not ideal for high traffic/high speed areas because it has lower load-bearing capacity than conventional pavement.

While the designs vary, all permeable pavements have a similar structure, consisting of a surface pavement layer, an underlying stone aggregate reservoir layer, optional underdrains, and geotextile over uncompacted soil subgrade.

From a hydrologic perspective, permeable pavement is typically designed to manage rainfall landing directly on the permeable pavement surface area. Permeable pavement surface areas may accept runoff contributed by adjacent impervious areas such as driving lanes or rooftops. Runoff from adjacent vegetated areas is often discouraged because sediment in runoff from adjacent areas increases clogging of the permeable pavement, especially at the edges. Additionally, the capacity of the underlying reservoir layer limits the contributing area.


Caution: Sediment control from adjacent impervious or vegetated contributing areas is required to avoid clogging of the permeable pavement surface


The individual articles comprising this section on permeable pavement may be viewed as a single article.

This photo illustrates an example of porous asphalt
This photo illustrates an example of porous asphalt
This photo illustrates an example of permeable interlocking pavement
This photo illustrates an example of permeable interlocking pavement


Porous pavement articles


Several fact sheets for permeable pavement provide overview information and information on design, construction and maintenance, and volume and pollutant removal.


While the designs vary, all permeable pavements have a similar structure, consisting of a surface pavement layer, an underlying stone aggregate reservoir layer, optional underdrains, and geotextile over uncompacted soil subgrade.


From a hydrologic perspective, permeable pavement is typically designed to manage rainfall landing directly on the permeable pavement surface area. Permeable pavement surface areas may accept runoff contributed by adjacent impervious areas such as driving lanes or rooftops. Runoff from adjacent vegetated areas is often discouraged because sediment in runoff from adjacent areas increases clogging of the permeable pavement, especially at the edges. Additionally, the capacity of the underlying reservoir layer limits the contributing area.


Caution: Sediment control from adjacent impervious or vegetated contributing areas is required to avoid clogging of the permeable pavement surface


The individual articles comprising this section on permeable pavement may be viewed as a single article.

This photo illustrates an example of porous asphalt
This photo illustrates an example of porous asphalt
This photo illustrates an example of permeable interlocking pavement
This photo illustrates an example of permeable interlocking pavement