Difference between revisions of "Dry ponds"
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*''f''' = design infiltration rate (mm/hr) | *''f''' = design infiltration rate (mm/hr) | ||
*''t'' = [[drainage time|time permitted for ponding to infiltrate]] (hrs) (typically 48 hours)}} | *''t'' = [[drainage time|time permitted for ponding to infiltrate]] (hrs) (typically 48 hours)}} | ||
| + | |||
| + | ===Outlet=== | ||
| + | Detention time | ||
| + | A detention time of 24 hours should be targeted in all instances. Where this necessaitates a very low outflow, a [[Flow control#Vo|vortex valve or similar is recommended over an orifice or pipe restiction. The detention time is approximated by the drawdown time. | ||
| + | |||
| + | The drawdown time in the pond can be estimated using Equation 4.10. Equation 4.10 is the classic falling head orifice equation which assumes a constant pond surface area. This assumption is generally not valid, and a more accurate estimation can be made if Equation 4.10 is solved as a differential equation. This is easily done if the relationship between pond surface area and pond depth is approximated using a linear regression. | ||
| + | |||
| + | Equation 4.10: Drawdown Time | ||
| + | |||
| + | t = start fraction 2 A subscript p over C A subscript o left-parenthesis 2 g right-parenthesis superscript 0 point 5 end fraction left-parenthesis h subscript 1 superscript 0 point 5 minus h subscript 2 superscript 0 point 5 right-parenthesis | ||
| + | |||
| + | or if a relationship between Ap and h is known (i.e., A = C2h + C3) | ||
| + | |||
| + | t = start fraction 0 point 66 C subscript 2 h superscript 1 point 5 + 2 C subscript 3 h superscript 0 point 5 over 2 point 75 A subscript o end fraction | ||
| + | |||
| + | where: | ||
| + | |||
| + | t | ||
| + | drawdown time in seconds | ||
| + | Ap | ||
| + | surface area of the pond(m²) | ||
| + | C | ||
| + | discharge coefficient (typically 0.63) | ||
| + | A0 | ||
| + | cross-sectional area of the orifice(m²) | ||
| + | g | ||
| + | gravitational acceleration constant (9.81,/s2) | ||
| + | h1 | ||
| + | starting water elevation above the orifice (m) | ||
| + | h2 | ||
| + | ending water elevation above the orifice (m) | ||
| + | C2 | ||
| + | slope coefficient from the area-depth linear regression | ||
| + | C3 | ||
| + | intercept from the area-depth linear regression | ||
| + | |||
| + | <ref>Ontario Ministry of Environment. (2003). Stormwater Management Planning and Design Manual. Retrieved January 15, 2017, from https://www.ontario.ca/document/stormwater-management-planning-and-design-manual/stormwater-management-plan-and-swmp-design</ref> | ||
| + | |||
===Excess flow control=== | ===Excess flow control=== | ||
Revision as of 20:25, 15 March 2018
Also known as infiltration basins or detention basins (according to their features). Dry ponds are a grassed alternative to bioretention cells. This permits the landscape to be accessed and used as an amenity space.
Overview[edit]
Dry ponds are recommended as flood control structures to accommodate occasional excess overflow downstream of other structural BMPs. They should be integrated into the landscape as useful, accessible public space.
Dry ponds are ideal for:
- Managing infrequent extreme flow events,
- incorporating into parks and other green recreational spaces,
- distributing across a larger development site
Design[edit]
Volume[edit]
The surface storage volume of a dry pond (Ap) is determined:
Where:
- RVCT = Runoff volume control target (mm)
- Ac = Area of the catchment (m2)
- f' = design infiltration rate (mm/hr)
- t = time permitted for ponding to infiltrate (hrs) (typically 48 hours)
Outlet[edit]
Detention time A detention time of 24 hours should be targeted in all instances. Where this necessaitates a very low outflow, a [[Flow control#Vo|vortex valve or similar is recommended over an orifice or pipe restiction. The detention time is approximated by the drawdown time.
The drawdown time in the pond can be estimated using Equation 4.10. Equation 4.10 is the classic falling head orifice equation which assumes a constant pond surface area. This assumption is generally not valid, and a more accurate estimation can be made if Equation 4.10 is solved as a differential equation. This is easily done if the relationship between pond surface area and pond depth is approximated using a linear regression.
Equation 4.10: Drawdown Time
t = start fraction 2 A subscript p over C A subscript o left-parenthesis 2 g right-parenthesis superscript 0 point 5 end fraction left-parenthesis h subscript 1 superscript 0 point 5 minus h subscript 2 superscript 0 point 5 right-parenthesis
or if a relationship between Ap and h is known (i.e., A = C2h + C3)
t = start fraction 0 point 66 C subscript 2 h superscript 1 point 5 + 2 C subscript 3 h superscript 0 point 5 over 2 point 75 A subscript o end fraction
where:
t drawdown time in seconds Ap surface area of the pond(m²) C discharge coefficient (typically 0.63) A0 cross-sectional area of the orifice(m²) g gravitational acceleration constant (9.81,/s2) h1 starting water elevation above the orifice (m) h2 ending water elevation above the orifice (m) C2 slope coefficient from the area-depth linear regression C3 intercept from the area-depth linear regression
Excess flow control[edit]
Modeling[edit]
| Stage Storage | |
|---|---|
| Name | Important to have a unique name, to connect it with the catchment area |
| Storage type | Dry detention ponds |
| Bottom elevation (m) | This is important to correspond with other components, e.g. when the overflow is coupled to another BMP within a treatment train |
| Maximum depth (m) | |
| Lined/unlined | Unlined (ideally) |
| Underlying soil | Choose from five; sandy soils drain more quickly. |
| Evaporation factor | ? |
| Suction head (mm) | ? |
| Saturated conductivity (mm/hr) | ? |
| Initial soil moisture deficit (fraction) | ? |
| Curves | |
| The Curves table is designed to accommodate the side slopes. The top line begins at 0 m, with subsequent depths in the following lines. | |
Materials[edit]
Resilient turf grasses are particularly useful in the design of vegetated filter strips, dry ponds and enhanced grass swales. The Ministry of Transportation have standardized a number of grass mixes[2]. The 'Salt Tolerant Mix' is of particular value for low impact development applications alongside asphalt roadways and paved walkways.
| Common name | Scientific name | Proportion |
|---|---|---|
| Tall Fescue | Festuca arundinacea | 25 % |
| Fults Alkali Grass | Puccinellia distans | 20 % |
| Creeping Red Fescue | Festuca rubra | 25 % |
| Perennial ryegrass | Lolium perrenne | 20 % |
| Hard Fescue | Festuca trachyphylla | 10 % |
Gallery[edit]
Wishing well park is a baseball field with flood warning signs, Scarborough ON
Avondale Park, designed for flood storage, but not optimized for infiltration, North York ON
A multi-functional dry basin, still due to be fitted with playground equipment. Cambridge, UK. Photo credit: Simon Bunn
Stormwater lagoon, Wilmhurst Road, Warwick. UK. Photo credit: Robin Stott
Dry polder northwest of Vincencov, Prostějov. Czech Republic. Photo credit: Jiří Komárek
- ↑ Ontario Ministry of Environment. (2003). Stormwater Management Planning and Design Manual. Retrieved January 15, 2017, from https://www.ontario.ca/document/stormwater-management-planning-and-design-manual/stormwater-management-plan-and-swmp-design
- ↑ Ontario Provincial Standard Specification. (2014). Construction Specification and for Seed and Cover OPSS.PROV 804. Retrieved from http://www.raqsb.mto.gov.on.ca/techpubs/ops.nsf/0/3a785d2f480f9349852580820062910a/$FILE/OPSS.PROV 804 Nov2014.pdf