Bioretention
This article is about planted installations designed to capture and filter surface runoff through engineered soil (filter media).
For simple systems (typically without regulatory control), 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 (LID). They can fit into any style of landscape and 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:
- A 'filter bed' containing an engineered soil mix
- A storage layer of coarse aggregate
- Planting and a finishing surface layer (e.g. mulch)
Additional components may include:
- An underdrain to redistribute or remove excess water
- An impermeable membrane to prevent infiltration to soils below
Planning considerations[edit]
Space
- For optimal performance bioretention facilities should receive runoff from between 5 to 20 times their own surface area.
- In the conceptual design stage it is recommended to set aside approximately 10 - 20 % of a catchment area to the bioretention facility.
- Bioretention cells work best when distributed, so that no one facility receives runoff from more than 0.8 Ha.
- Although, there is a trade off to be considered regarding distributed collection and treatment against ease of maintenance.
- Bioretention can be almost any shape, from very curving, soft edges with variable depth, to angular, hard sided and uniform depth.
- For ease of construction and to ensure that the vegetation has adequate space, cells should be no narrower than 0.6 m at any point.
- The maximum width of a facility is determined by the reach of the construction machinery, which must not be tracked into the cell.
Infiltration
Some form of stormwater landscaping (bioretention) can be fitted into most spaces. One of the key decisions is whether to infiltrate all of some of the collected water into the native soil. Although there are some constraints to infiltrating water, it is preferable to do so where possible. Partial infiltration facilities are a popular choice over 'tight' soils (infiltration ≤ 15 mm/hr).
| Type | Gravel layer | Underdrain | Liner | Mechanisms | Schematic |
|---|---|---|---|---|---|
| Rain gardens | - | - | - | These are the simplest construction, often used by residents or community groups. Volume reduction is through infiltration and evapotranspiration. | 
|
| Infiltrating bioretention | yes | - | - | This is a highly desirable type of bioretention where the soils permit infiltration at a great enough rate to empty the facility between storm events. Volume reduction is primarily through infiltration to the underlying soils, with some evapotranspiration. As there is no outflow from this BMP, it is particularly useful in areas where nutrient management is a concern to the watershed. | 
|
| Partially infiltrating bioretention | yes | yes | - | Including an underdrain in the gravel storage layer help to empty the facility between storm events, even over ‘tight soils’. The drain discharges to a downstream point, which could be an underground infiltration facility. Limited volume reduction is gained through infiltration and evapotranspiration. By raising the outlet of the discharge pipe the bottom portion of the BMP can only drain through infiltration. This creates a fluctuating anaerobic/aerobic environment which promotes denitrification. Increasing the period of storage has benefits for promoting infiltration, but also improves water quality for catchments impacted with nitrates. A complimentary technique is to use fresh wood mulch, which also fosters denitrifying biological processes. |  
|
| Biofilters (non-infiltrating) |
yes | yes | yes | This type may be required over contamination hot-spots or in very dense urban areas with a lot of other underground infrastructure. The design includes an impermeable base and sides, so that volume reduction is made only through evapotranspiration. This type of cell can be constructed above grade in any waterproof and structurally sound container, e.g. in cast concrete or a metal tank. | 
|
Inlets and pretreatment options
Options for pretreatment include:
- A gravel diaphragm for sheet flow
- Vegetated filter strips for sheet flow
- A forebay for concentrated overground flow
- An oil and grit separator for concentrated underground flow
Simple (non-treating) inlets include:
- Sheet flow from a depressed curb
- One of more curb cuts
- Covered drains
Overflow routing
Design for maintenance
Design[edit]
Sizing
Bioretention cells should be sized to accommodate runoff from approximately 5 to 20 times the footprint area of the facility. i.e. I/P ratio of 5 to 20.
Equations and a tool to help with sizing infiltration practices
Submissions
Plant Selection[edit]
- Exposure to roadway or parking lot runoff
- Select salt tolerant grasses, other herbaceous material and shrubs.
- These can take on several forms, including parking lot islands, traffic islands, roundabouts, or cul-de-sacs and are often used as snow storage locations.
- No exposure to roadway or parking lot runoff
- Practices allow for a greater range of species selection.
- These receive runoff from rooftops or areas that use no deicing salt and have low pollutant exposure, such as courtyard bioretention.
Other selection factors:
- Most bioretention cells will be situated to receive full sun exposure. The ‘Exposure’ column in the master plant list identifies the sun exposure condition for each species.
- Facilities with a deeper media bed (greater than 1 m) provide the opportunity for a wider range of plant species (including trees).
- The inclusion of vegetation with a variety of moisture tolerances ensures that the bioretention cell will adapt to a variety of weather conditions.
- Proper spacing must be provided for above-ground and below-ground utilities, and adjacent infrastructure.
See Plant Standards for specific plant species and sizes.
Construction[edit]
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
Sustainable sites: Rainwater management (up to 3 points)
- Two points (or 1 point for Healthcare) will be awarded if the project manages "the runoff from the developed site for the 95th percentile of regional or local rainfall events."
- Three points (or 2 points for Healthcare) will be awarded if the project manages "the runoff from the developed site for the 98th percentile of regional or local rainfall events."
OR
- For zero-lot-line projects only, 3 points (or 2 points for Healthcare) will be awarded if the project manages "the runoff from the developed site for the 85th percentile of regional or local rainfall events."