Compressed Air Pressure Drop Across a Restriction

AI Thread Summary
The discussion focuses on calculating the pressure drop of compressed air as it flows from a 3" diameter pipe through a bell reducer to a 1.5" diameter pipe. Participants seek formulas for determining the pressure drop at a constant flow rate and how it changes when the flow rate is doubled. A recommended resource for understanding the physics of compressed air in industrial systems is Crane Technical Paper 410, which is applicable to both liquids and gases. Despite initial concerns about its focus on liquids, it is confirmed to include relevant information for gas flow. The consensus is that TP 410 is a valuable starting point for non-engineers interested in compressed air systems.
SteveRomero
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I would like the formula that describes the reduction in pressure that results when a constant flow (cfm) of compressed air travels from a 3" diameter pipe through a bell reducer that provides a smooth transition to a 1.5" diameter pipe.

Also, in the same piping configuration as described above, if the pressure drop is X psid acress the reducer, what will the pisd be if the cfm were doubled? What is the formula for this relationship as well?

Is there a textbook that is available for non-engineers that describes the physics of compressed air in industrial compressed air systems?

Thanks a million.
 
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SteveRomero said:
Is there a textbook that is available for non-engineers that describes the physics of compressed air in industrial compressed air systems?

This is probably your best bet:

http://www.flowoffluids.com/tp410.htm

CS
 
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Thanks . . .
. . . CS, for your help. The publication that you identified appears to be specifically for liquid fluids . . . I need compressed air information. Do both liguids and gases follow the same physics?
 
Hi Steve,
The book stewartcs points out (Crane technical paper 410) is the bible of the industry. Process work throughout industry relies on it for fluid flow through piping systems. The paper specifically calls out where it is applicable and where not, so yes, it's applicable to compressed gas systems.
 
SteveRomero said:
Thanks . . .
. . . CS, for your help. The publication that you identified appears to be specifically for liquid fluids . . . I need compressed air information. Do both liguids and gases follow the same physics?

TP 410 does include gas flow as well as Q pointed out. It would be a great place for you to start.

CS
 
Thanks again. Crane TP 410 is where I will begin my search.

Steve
 

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