Editing Permeable paving (section)

== Description and applications ==
[[File:Inrit parkeergarage in grastegels, Veemarkt Utrecht (51197027460).jpg|thumb|right|Grass pavers being used for a permeable driveway in the Netherlands]]
Permeable solutions can be based on porous asphalt and concrete surfaces, concrete pavers (permeable interlocking concrete paving systems – PICP), or polymer-based grass pavers, grids and geocells. Porous pavements such as [[pervious concrete]] and pervious asphalt are better suited for urbanized areas that see more frequent vehicular traffic, while concrete pavers, grids, and geocells are better suited for light vehicular traffic, pedestrian and cycling pathways, and overflow parking lots.<ref name="Scholz2007">{{Cite journal|last=Scholz|first=Miklas|date=2007-11-16|title=Review of permeable paving systems|url=https://www.sciencedirect.com/science/article/pii/S0360132306004227|access-date=2020-12-04|journal=Building and Environment|volume=42 |issue=11 |pages=3830–3836 |doi=10.1016/j.buildenv.2006.11.016 |language=en}}</ref> Pervious concrete pavers allow water to percolate and infiltrate through the pavers and into the aggregate layers and/or soil below. Impervious concrete pavers installed with ample void space between each paver function in the same way as pervious concrete pavers as they enable stormwater to drain into the voids between each paver, either filled with coarse aggregate or vegetation, to a stone and/or soil base layer for on-site infiltration and filtering.<ref>{{Cite web|url=https://stormwater.wef.org/2013/10/pervious-permeable-porous-pavers-really/|title=Are Pervious, Permeable, and Porous Pavers Really the Same?|last=Walker|first=Mark|date=2013-10-02|website=Water Environment Foundation|language=en|access-date=2020-12-05}}</ref> Polymer based grass grid or cellular paver systems provide load bearing reinforcement for unpaved surfaces of gravel or turf.

Grass pavers, plastic turf reinforcing grids (PTRG), and geocells ([[cellular confinement systems]]) are honeycombed 3D grid-cellular systems, made of thin-walled [[HDPE]] plastic or other polymer alloys. These provide grass reinforcement, ground stabilization and gravel retention. The 3D structure reinforces infill and transfers vertical loads from the surface, distributing them over a wider area. Selection of the type of cellular grid depends to an extent on the surface material, traffic and loads. The cellular grids are installed on a prepared base layer of open-graded stone (higher void spacing) or engineered stone (stronger). The surface layer may be compacted gravel or [[topsoil]] seeded with grass and fertilizer. In addition to load support, the cellular grid reduces compaction of the soil to maintain permeability, while the roots improve permeability due to their root channels.<ref>Stormwater Management, http://www.epa.gov/oaintrnt/stormwater/index.htm</ref>

In new suburban growth, porous pavements protect [[drainage basin|watersheds]] by delaying and filtering the surge flow. In existing built-up areas and towns, redevelopment and reconstruction are opportunities to implement stormwater water management practices. Permeable paving is an important component in [[Low-impact development (Canada/US)|Low Impact Development]] (LID), a process for [[land development]] in the United States that attempts to minimize impacts on [[water quality]] and the similar concept of [[sustainable drainage system]]s (SuDS) in the United Kingdom.

The [[infiltration (hydrology)|infiltration]] capacity of the native soil is a key design consideration for determining the depth of base rock for stormwater storage or for whether an underdrain system is needed.