Difference between revisions of "Flow through perforated pipe"

Revision as of 03:13, 25 February 2018

Manufacturers of perforated pipe are often able to provide the open area (m²) per meter length.

$Q_{max,p}=B\times C_{d}\times A_{o}{\sqrt {2\cdot g\cdot \sum d}}$

Where:_d is the coefficient of discharge (0.61 for a sharp edged orifice),

B is the clogging factor (between 0.5 to calculate a for matured installation and 1 to calculate a new perfectly performing BMP),
C_d is the coefficient of discharge (usually 0.61 for the sharp edge created by relatively thin pipe walls),
A_o is the total open area per unit length of pipe (m²/m),
g is acceleration due to gravity (m/s²)
Σ d is the total depth of bioretention components over the perforated pipe (mm) (e.g. ponding/mulch/filter media/choker layer),
O is the number of orifices per meter of perforated pipe.

@@ Line 5: / Line 5: @@
 *''B'' is the clogging factor (between 0.5 to calculate a for matured installation and 1 to calculate a new perfectly performing BMP),
 *''C<sub>d</sub>'' is the coefficient of discharge (usually 0.61 for the sharp edge created by relatively thin pipe walls),
-*''A<sub>o</sub>'' is the total open area of the perforated pipe (m<sup>2</sup>/m),
+*''A<sub>o</sub>'' is the total open area per unit length of pipe (m<sup>2</sup>/m),
 *''g'' is acceleration due to gravity (m/s<sup>2</sup>)
 *''Σ d'' is the total depth of bioretention components over the perforated pipe (mm) (e.g. ponding/[[mulch]]/[[filter media]]/[[choker layer]]),
+*''O'' is the number of orifices per meter of perforated pipe.
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