Difference between revisions of "Infiltration"
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Infiltration of stormwater into underlying soils is one mechanism to achieving MECP [[runoff volume control targets]]. In many areas of Ontario, where municipal supplies | Infiltration of stormwater into underlying native subgrade soils is one mechanism to achieving MECP [[runoff volume control targets]]. In many areas of Ontario, where municipal and private drinking water supplies are drawn from aquifers, it's also an important mechanism for groundwater recharge. | ||
{{textbox| | {{textbox|Drainage via infiltration be achieved through a number of LID BMP types: | ||
*[[Infiltration chambers]] (underground) | *[[Infiltration chambers]] (underground) | ||
*[[Infiltration trenches]] (underground) | *[[Infiltration trenches]] (underground) | ||
*[[Bioretention]] (surface) | *[[Exfiltration trenches| Exfiltration systems]] (underground) | ||
*[[Bioswales]] (surface) | *[[Bioretention]] (surface, full- or partial-infiltration design variations) | ||
*[[ | *[[Bioswales]] (surface, full- or partial-infiltration design variations) | ||
*[[ | *[[Permeable pavements| Permeable pavements]] (surface, full- or partial-infiltration design variations) | ||
*[[Dry ponds]] (surface) | *[[Stormwater Tree Trenches|Stormwater tree trenches]] (surface) | ||
*[[Enhanced swales]] featuring check dams (surface) | |||
*[[Dry ponds]] or infiltration basins (surface) | |||
}} | }} | ||
==Constraints== | ==Constraints== | ||
Infiltration practices are not recommended: | Infiltration practices are not recommended: | ||
#over-swelling clays or unstable | #over-swelling clays or unstable subsoils, | ||
#contaminated soils or sites with high risk of contamination from | #contaminated soils or sites with high risk of contamination from on-site activities (i.e. pollution hot spots), | ||
#in flood prone areas where the wastewater system is sensitive to groundwater conditions causing sewer backups | #in areas of known or implied karst topography, | ||
#on unstable or steep slopes (>15%), | |||
# to treat construction site runoff, | |||
#to treat combined sewer overflows, | |||
#in flood prone areas where the wastewater system is sensitive to groundwater conditions causing sewer backups, | |||
#in areas where the ecology and natural hydrology are dependent upon surface water, | #in areas where the ecology and natural hydrology are dependent upon surface water, | ||
#in areas where increased infiltration will result in elevated groundwater levels | #in areas where increased infiltration will result in elevated groundwater levels that will damage critical utilities or private property, or | ||
#where prohibitions and/or restrictions exist per approved Source Protection Plans (see MOECC guidance). | #where prohibitions and/or restrictions exist per approved Drinking Water Source Protection Plans (e.g. should not be used to treat pavement runoff within 2 year time of travel wellhead protection areas; see MOECC guidance). | ||
<br> | <br> | ||
Infiltration facilities should be designed with | See [[Site considerations]] for further guidance on potential site constraints and LID facility type selection and design considerations. | ||
===Designing with constraints=== | |||
{{textbox|Infiltration facilities can be effective on low permeability soils with infiltration rates ≤ 15 mm/hr: | |||
*See [[Underdrains| underdrains]] and | |||
*Results from STEP studies of infiltration facilities located on [[low permeability soils]] in Ontario. | |||
Infiltration facilities should be designed with modifications where: | |||
#the underlying bedrock is within 1 m below the bottom of the proposed BMP, or | #the underlying bedrock is within 1 m below the bottom of the proposed BMP, or | ||
#the seasonal high groundwater level comes within 1 m below the bottom of the proposed BMP. | #the seasonal high groundwater level (i.e. water table) comes within 1 m below the bottom of the proposed BMP. | ||
}} | }} | ||
{{:Groundwater}} | |||
==Planning== | ==Planning== | ||
===Hydrogeology=== | ===Hydrogeology=== | ||
The Conservation Authorities Geoscience Group has prepared a guidance document which attempts to standardize the hydrogeological study requirements for development applications made to Conservation Authorities. It is a helpful guide for all low impact development applications which include infiltration. It is provided with the caveat that not all sections or content are necessary or appropriate for every case. Pre-consultation with your | The Conservation Authorities Geoscience Group has prepared a guidance document which attempts to standardize the hydrogeological study requirements for development applications made to Conservation Authorities. It is a helpful guide for all low impact development applications which include infiltration. It is provided with the caveat that not all sections or content are necessary or appropriate for every case. Pre-consultation with your local conservation authority and municipality is strongly recommended in all cases. | ||
'''[http://www.lsrca.on.ca/Shared%20Documents/permits/hydrogeological%20_guidelines.pdf?pdf=Hydrogeological-Guidelines Hydrogeological Assessment Submissions Conservation Authority Guidelines for Development Applications]''' | '''[http://www.lsrca.on.ca/Shared%20Documents/permits/hydrogeological%20_guidelines.pdf?pdf=Hydrogeological-Guidelines Hydrogeological Assessment Submissions Conservation Authority Guidelines for Development Applications]''' | ||
==Beginning | ==Beginning an infiltration BMP design?== | ||
See [[Design infiltration rates]] | See [[Design infiltration rates]] | ||
---- | ---- | ||
==See also== | ==See also== | ||
*[[ | *[[Site considerations]] | ||
[[category:Infiltration]] | [[category:Infiltration]] |
Latest revision as of 21:32, 10 March 2022
Infiltration of stormwater into underlying native subgrade soils is one mechanism to achieving MECP runoff volume control targets. In many areas of Ontario, where municipal and private drinking water supplies are drawn from aquifers, it's also an important mechanism for groundwater recharge.
Drainage via infiltration be achieved through a number of LID BMP types:
- Infiltration chambers (underground)
- Infiltration trenches (underground)
- Exfiltration systems (underground)
- Bioretention (surface, full- or partial-infiltration design variations)
- Bioswales (surface, full- or partial-infiltration design variations)
- Permeable pavements (surface, full- or partial-infiltration design variations)
- Stormwater tree trenches (surface)
- Enhanced swales featuring check dams (surface)
- Dry ponds or infiltration basins (surface)
Constraints[edit]
Infiltration practices are not recommended:
- over-swelling clays or unstable subsoils,
- contaminated soils or sites with high risk of contamination from on-site activities (i.e. pollution hot spots),
- in areas of known or implied karst topography,
- on unstable or steep slopes (>15%),
- to treat construction site runoff,
- to treat combined sewer overflows,
- in flood prone areas where the wastewater system is sensitive to groundwater conditions causing sewer backups,
- in areas where the ecology and natural hydrology are dependent upon surface water,
- in areas where increased infiltration will result in elevated groundwater levels that will damage critical utilities or private property, or
- where prohibitions and/or restrictions exist per approved Drinking Water Source Protection Plans (e.g. should not be used to treat pavement runoff within 2 year time of travel wellhead protection areas; see MOECC guidance).
See Site considerations for further guidance on potential site constraints and LID facility type selection and design considerations.
Designing with constraints[edit]
Infiltration facilities can be effective on low permeability soils with infiltration rates ≤ 15 mm/hr:
- See underdrains and
- Results from STEP studies of infiltration facilities located on low permeability soils in Ontario.
Infiltration facilities should be designed with modifications where:
- the underlying bedrock is within 1 m below the bottom of the proposed BMP, or
- the seasonal high groundwater level (i.e. water table) comes within 1 m below the bottom of the proposed BMP.
Target groundwater separation[edit]
In many areas of Ontario the target separation between the base of an exfiltrating LID practice and the water table is 1.0 m. This is to mitigate risks due to short periods of groundwater mounding and potentially unobserved seasonal fluctuations. In areas where a 1.0 m separation cannot be provided, or where conditions dictate that an even greater separation may be warranted, additional discussion and/or analysis specific to the physical characteristics of the site and the proposed design should be completed. The design practitioner is advised to consult with approval agencies to understand their requirements and/or expectations prior to undertaking work, and to complete an appropriate level of analysis to support their conclusion. The requirement for additional investigation and/or documentation supporting a proposed design may be reduced in areas where ≥ 1.0 m separation is anticipated.
Retention of an unsaturated zone beneath the practice :
- Minimizes the potential for functional impacts associated with reduced percolation rates,
- Maintains the physical and biochemical water quality treatment benefits provided within the vadose zone.
Groundwater mounding[edit]
Groundwater mounding describes the localised raising of the water table beneath infiltration practices. It may be of concern if it affects nearby structures including building foundations. When you wish to model the extent of groundwater mounding beneath an infiltration facility, use this Tool that incorporates Hantush's derivation (1967).
Note that this is a minor adaptation (metric units and formatting) from the original tool, written and hosted by the USGS.
Preventing groundwater interaction[edit]
Many LID systems rely upon reuse, or evaporation and transpiration instead of infiltration to the ground. If the site cannot support any infiltration, consider
Oak Ridges Moraine Groundwater Program[edit]
The Oak Ridges Moraine focused program stretches from the Credit and Nottawasaga River watersheds in the west to the Trent River in the east and reaches from the shores of Lake Ontario northwards to beyond Lake Simcoe and the Kawartha Lakes. Within the publicly accessible maps section there is a depth to water table map layer.
Other sources of groundwater data[edit]
Planning[edit]
Hydrogeology[edit]
The Conservation Authorities Geoscience Group has prepared a guidance document which attempts to standardize the hydrogeological study requirements for development applications made to Conservation Authorities. It is a helpful guide for all low impact development applications which include infiltration. It is provided with the caveat that not all sections or content are necessary or appropriate for every case. Pre-consultation with your local conservation authority and municipality is strongly recommended in all cases.