Pressure drop across an orifice (Orifice pressure drop in meters?)

AI Thread Summary
The discussion centers on calculating the pressure drop across an orifice and converting that pressure drop from Pascals to meters of pressure head. The initial pressure drop is given as 470.72 Pa, and the conversion formula involves dividing by the product of density and gravitational acceleration. A user expresses confusion about whether they have the correct ΔP value and whether they need to refer to an air properties table for density at a specific temperature. The calculation provided yields an orifice pressure drop of 42.34 meters, which is questioned as being excessively large. The conversation highlights the complexities of dealing with compressible gases in such calculations.
scottniblock
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Homework Statement



ΔP = 1000 x 9.81 x (Orifice pressure drop in m)

Pressure drop across orifice = 470.72 Pa


2. Homework Equations



3. The Attempt at a Solution

I am not sure how this works. How can pressure be converted to meters? It does not make sense to me.

Any help would be much appreciated

Thanks
Scott
 
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To convert a pressure (Pa) to a pressure head (m) divide by ρg (N/m^3).
 
Hi,

Thank you for the reply. Still slightly confused.

It is ΔP that I need to find in order to calculate the ideal mass flowrate of air.

Do I already have the answer to the question, ie ΔP = 470.72 Pa ?
 
or do I need to use an Air properties table to find ρ at the temperature I am given?
 
Question

Orifice pressure drop in meters = (Pa (N/m^2 ))/(ρg (N/m^3 )) This gives answer in meters


Question 1

Given:
T = 312 K
ρ = 1.1333 kg/m^3 (From Air properties table)
g = 9.81 m/s^2

Orifice pressure drop = 470.72 Pa

Calculation:

Orifice pressure drop in meters = 470.72 / (9.81x1.1333) = 42.34 meters

This answer does not seem right, looks way too large.
 
Sorry, I thought you were only looking for the conversion and I assumed you were talking about an incompressible fluid not a compressible gas. So I can't help you there.
 

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