Difference between revisions of "Bioretention"
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Revision as of 22:08, 29 June 2017
This article is about planted installations designed to capture surface runoff through an engineered soil with subterranean infrastructure.
For simpler, residential systems, see Rain gardens.
For linear systems, which convey flow, but are otherwise similar see Bioswales.
Overview[edit]
Bioretention cells are one of the most well recognized form of Low Impact Development. They can encompass all mechanisms of action: infiltration, filtration and evapotranspiration.
Bioretention cells are an ideal technology for:
- Fitting functional vegetation into urban landscapes
- Treating runoff collected from nearby impervious surfaces
The fundamental components of a bioretention cell are:
- Biomedia: An engineered soil mix
- Planting
- Storage layer of coarse aggregate
- Under-drain to redistribute or remove excess water
- Impermeable membrane to prevent infiltration to soils below
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These bioretention cells at Edwards Gardens in Toronto receive inflow from hydraulically connected permeable paving.
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Design for maintenance
Will the BMP be a snow storage facility in winter months?
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Bioretention cell capturing and treating runoff from adjacent parking lot at the Kortright Centre, Vaughan.
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Design[edit]
Perforated pipes are a common component of underdrains used in bioretention, permeable pavements, infiltration trenches and exfiltration systems.
Pipes should be manufactured in conformity with the latest standards by the Canadian Standards Association (CSA) or ASTM International.
- Perforated pipes should be continuously perforated, smooth interior HDPE or PVC.
- Wherever possible pipes should be ≥200 mm internal diameter to reduce potential of freezing and to facilitate push camera inspections and cleaning with jet nozzle equipment.
- Smooth interior facilitates inspection and maintenance activities; internal corrugations can cause cameras or hydrojetting apparatus to become snagged.
- A perforated pipe with many rectangular slots has better drainage characteristics than a pipe with similar open area provided by fewer circular holes [1].
- Non-perforated pipes should be used for conveyance of stormwater to and from the facility, including overflow. It is good practice to extend the solid pipe approximately 300 mm within the reservoir or practice to reduce the potential for native soil migration into the pipe.
Pipe with slotted perforations
Perforated pipes awaiting installation, note the 45 degree couplings used to facilitate push camera inspection and jet nozzle cleaning.
See also: Flow through perforated pipe
Vegetation
For a detailed list of recommend plant species, see Plants for bioretention
- The vegetation is a big opportunity to maximize the co-benefits of biodiversity and amenity. Planting plans can be formalized or naturalized to suit the surrounding style.
- For resilient and robust planting, native species which can tolerate periods of drought and periodic inundation are recommended.
- Woody and evergreen plants should be avoided in any areas of the bioretention cell to be used as snow storage.
- Dense shrubby plants should be avoided in locations where the accumultion of trash is anticipated as a maintenance problem.
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Bioretention cell capturing and treating runoff from adjacent parking lot at the Kortright Centre, Vaughan.
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Performance[edit]
Performance Content
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Bioretention cell capturing and treating runoff from adjacent parking lot at the Kortright Centre, Vaughan.
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Incentives and Credits[edit]
In Ontario
City of Mississauga
The City of Mississauga has a stormwater management credit program which includes RWH as one of their recommended site strategies[1].
LEED BD + C v. 4
SITES v.2
See Also[edit]
External Links[edit]
[edit]
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- ↑ Hazenberg, G., and U. S. Panu (1991), Theoretical analysis of flow rate into perforated drain tubes, Water Resour. Res., 27(7), 1411–1418, doi:10.1029/91WR00779.