There are so many standards out there today on the definition of SCFM.

SCFM is defined today by CAGI (Compressed Air and Gas Institute) as 14.5 psia, 68° F with 0% RH.

Some additional standards on the market today are 14.696, 70°F with 0% RH and 14.7 psia, 68°F with 0% RH. Some consider SFCM as NCFM (Normal cubic feet per minute) this is a 14.7 psia, 68°F with 36% RH.

All these different standards can be calculated using the same calculation. We just need to know what the starting point and ending points. As 1 bar equals 14.5 psia and 68° F equals 20° C is it reasonable that we use the current CAGI standard of 14.5 psia, 68° F with 0% RH as this will also cross over to the metric world simply.

So what or how does the effect the user or manufacture of the compressors. Simple stated if the compressor manufacture is stating their compressor produces 500 CFM as FAD (Free Air Delivery) @ 14.5 psia, 68° F with 0% RH doesn’t this mean that you get 500 CFM. The answer is no unless you’re inlet conditions equal 14.5 psia, 68° F with 0% RH and this is never the case. We must correct to the actual site conditions. Using Denver as an extreme with an altitude of 5280 Feet on a 90°F day with 45% RH the actual output of the compressor can be quite different then the name plate of the compressor.

ACFM = SCFM * ((P_{s} – (RH_{s} * PV_{s})/ P_{b} -(RH_{a} * PV_{a})) * (T_{a}/T_{s}) * (P_{b}/P_{a})

Where:

P_{s} = Standard pressure (PSIA)

P_{b} = Atmospheric pressure – barometer (PSIA)

P_{a} = Actual pressure (PSIA)

RH_{s} = Standard relative humidity

RH_{a} = Actual relative humidity

PV_{s} = Saturated vapor pressure of water at standard temperature (PSIa)

PV_{a} = Saturated vapor pressure of water at actual temperature (PSIa)

T_{s} = Standard temperature (°R) NOTE: °R =°F+459.67

Given the example from Denver

500 CFM

90°F

45% RH

ACFM =500 * ((14.5 – (0.0% * .3418)/(12.09 – (45% * .6988))) – ((90+459.67)/(68+459.67)) * (12.09/11.78)

This is gives us a 390 CFM. So if the requirement was 500 cfm and one purchased a 500 cfm Compressor rated at 14.5 psia, 68° F with 0% RH in Denver the end result would be that you where 22% short on the compressed air.

ICFM to ACFM

ICFM (Inlet Cubic Feet per Minute) is used by some compressor manufactures to covey conditions before additional items such as inlet filter, blower, or booster. If the pressures and temperatures are the same after the components then ACFM and ICFM are the same, but there are always pressure drops or rise will occur after the additional items listed.

The equation from ICFM to ACFM can be expressed as the follows:

ACFM = ICFM * ( P_{act}/ P_{f}) * (T_{f} / T_{act})

Where:

P_{act} = pressure actual before filter or other items (PSIA)

P_{f }= pressure after filter or other items (PSIA)

T_{f }= Temperature after the filter or other items (°R)

T_{act }= Temperature actual before filter or other items (°R)

Note:

The ideal gas law is accurate at lower pressures and high temperatures. To account for pressure and temperatures deviation from the ideal situation the True Gas law or non-ideal gas law must be used.

PV = Z n R T

Z = Gas Compressibility factor

N = number of moles of gas present

This is especially handy when working gas mixtures.