Flow through perforated pipe

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

${\frac {Q_{max,p}=L\times B\times C_{d}\times A_{o}{\sqrt {2\cdot g\cdot \sum d}}}{1000}}$

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

L is the length of perforated pipe (m)
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 (m) (e.g. ponding/mulch/filter media/choker layer),

Example calculation[edit]

A part used roll of 100 mm diameter perforated pipe will be used for a stormwater planter project, where each planter will be 8 meters long. The initial design for the planters includes 750 mm depth of filter medium, 50 mm rock mulch, and a further ponding of 300 mm. Upon inspection the pipe is found to have perforations of 8 mm x 1.5 mm on six sides, repeated every 3 cm along the pipe. To calculate the maximum flow rate from each planter, first the open area of the pipe must be calculated in m²/m: ${\frac {0.008\ m\times 0.0015\ m\times 6}{0.03\ m}}=0.0024\ m^{2}/m$ Then the maximum flow rate per planter is calculated: $Q_{max,p}={\frac {8\times 0.5\times 0.61\times 0.0024\ m^{2}/m{\sqrt {2\cdot 9.81\ m/s^{2}\cdot \sum 1.1\ m}}}{1000}}=27\ L/s$

Flow through perforated pipe

Example calculation[edit]

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