Difference between revisions of "Infiltration: Sizing and modeling"

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The sizing calculations require that most of the following parameters be known or estimated. The exceptions are the depth (d) and the permeable footprint area of the practice (Ap), as only one of these is required to find the other. Note that some of these parameters can be limited by site conditions and factors influencing constructability:

1. The maximum total depth will be limited by construction practices i.e. usually ≤ 2 m to avoid the need for benching and shoring open cut excavations.
2. The maximum total depth may be limited by the conditions underground (e.g. water table or underlying geology/infrastructure).
3. The maximum total depth may be limited by the desire to install the practice below the maximum frost penetration depth in the proposed location.
4. The maximum total depth may be limited by the desire to support vegetation cover over it (e.g. at least 30 cm of planting soil backfill over the BMP to support grasses)
5. Infiltration trenches, chambers and bioretention have a maximum recommended I/P ratio of 20.

This spreadsheet tool has been set up to perform all of the infiltration practice sizing calculations shown below
Download Infiltration Sizing.xlsx calculator tool

To calculate the required depth, where the area of the facility is constrained (3D drainage)[edit]

In some very constrained sites, the surface area of the BMP may be limited, in this case the required depth of cell or trench can be calculated:

${\displaystyle d=a[e^{\left(-bD\right)}-1]}$

Where ${\displaystyle a={\frac {Ap}{x}}-{\frac {iAi}{Apf'}}}$ and ${\displaystyle b={\frac {xf'}{nAp}}}$

(The rearrangement to calculate the required footprint area of the facility for a given depth using three dimensional drainage is not available at this time. Elegant submissions are invited.)

To calculate the required depth, where the area of the facility is constrained (1D drainage)[edit]

In some very constrained sites, the surface area of the BMP may be limited, in this case the required depth of cell or trench can be calculated. Note that in most cases the results of this calculation will be very similar to those of the above equation using 3D infiltration.

${\displaystyle d={\frac {D\left[\left({\frac {Ai}{Ap}}\right)i-f'\right]}{n}}}$

To calculate the require facility area or footprint where the depth is constrained (1D drainage)[edit]

In many locations throughout Ontario, there may be limited depth of soil available into which stormwater may be infiltrated. In this case the required storage needs to be distributed more widely across the landscape. The overall are of BMP required can be calculated: ${\displaystyle Ap={\frac {iDAi}{nd+f'D}}}$

Time for infiltration of surface ponded water[edit]

The following equation assumes that infiltration occurs primarily through the footprint of the facility. It is best applied to calculate the maximum duration of ponding on the surface of bioretention cells, and upstream of check dams of bioswales and enhanced grass swales to ensure all surface ponding drains within 48 hours. To calculate the time (t) to fully drain surface ponded water through the filter media or planting soil: ${\displaystyle t={\frac {d}{K}}}$ Where d is the mean ponding depth

Drainage time to empty facility[edit]

Three footprint areas of 9 m².
From left to right x = 12 m, x = 20 m

The target drainage time for the internal storage of an infiltration facility is typically between 48 and 72 hours or based on the average inter-event period for the location. See Drainage time for more information about how inter-event periods vary across Ontario and to help select what is suitable for the site.

Try the Darcy Drainage calculator tool for estimating drainage time assuming either one or three-dimensional drainage from the practice:
Download drainage time calculator(.xlsx)

For some geometries (e.g. particularly deep facilities or linear facilities), it preferable to account for lateral infiltration. The 3D equation make use of the hydraulic radius (A_p/x), where x is the perimeter (m) of the facility.
Maximizing the perimeter of the facility directs designers towards longer, linear shapes such as infiltration trenches and bioswales.

To calculate the time (t) to fully drain the facility: ${\displaystyle t={\frac {nAp}{f'x}}ln\left[{\frac {\left(d+{\frac {Ap}{x}}\right)}{\left({\frac {Ap}{x}}\right)}}\right]}$ Where "ln" means natural logarithm of the term in square brackets