How to find water vapor volume at different pressures than atm?

AI Thread Summary
To find the water vapor volume at different pressures, the ideal gas law can be applied using the pressure ratio. The correct calculation for the volume change when moving from 14.7 psi to 10 psi is 300 L multiplied by (14.7 psi / 10 psi), resulting in approximately 441 liters, assuming constant temperature. For a more accurate result, utilizing steam tables is recommended, where the specific volume at the desired pressure must be referenced. To convert the volume of water vapor to mass, the specific volume at the initial pressure should be used to determine the mass in kilograms. Accurate calculations rely on maintaining consistent temperature throughout the process.
rhinohugger
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Homework Statement


If a known amount, let's say 300 liters of water gas (water vapor) is flowing from an atmospheric (14.7 psi) source/chamber, into a chamber of reduced pressure of 10 psi, does the volume amount and/or moles change?


Homework Equations


So I believe I would multiply the 300 liters by the pressure ratio, but not sure which pressure value is the denominator, which is the numerator


The Attempt at a Solution


I believe its either: 300 L * (10psi / 14.7 psi) which is 204.1 liters,
or it is: 300 L * (14.7 psi / 10 psi) which is 441 liters

Thanks for any help, I am leaning more towards 441 liters as my answer
 
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Hi rhinohugger. Welcome to Physics Forums.

If the new chamber were initially empty (vacuum) and you could get all the moles into the new chamber at 10 psi, and, if the temperature were held fixed, then using the ideal gas law the way you did would give you a pretty accurate answer. If you needed a more accurate answer, you would have to use a more accurate equation of state, or you could use the steam tables (which have the specific volumes at various temperatures and pressures tabulated for you).

Chet
 
Thanks for the quick reply Chet,
1.So to clarify, the ideal gas method of 300 L * (14.7 psi / 10 psi) [NOT 10 psi /14 psi], would provide an accurate answer?
2. Also, I am looking at a steam table currently on engineering toolbox.
To use one to find a more accurate answer, I would look at the pressure on the steam chart (10 psi, in my case) and look find the specific volume which is in m^3/kg, so I would have to first calculate how many kg are in 300 liters of water vapor at 14.7 psi, and multiply it by the specific volume?
 
rhinohugger said:
Thanks for the quick reply Chet,
1.So to clarify, the ideal gas method of 300 L * (14.7 psi / 10 psi) [NOT 10 psi /14 psi], would provide an accurate answer?
Yes, as long as it is at the same temperature.
2. Also, I am looking at a steam table currently on engineering toolbox.
To use one to find a more accurate answer, I would look at the pressure on the steam chart (10 psi, in my case) and look find the specific volume which is in m^3/kg, so I would have to first calculate how many kg are in 300 liters of water vapor at 14.7 psi, and multiply it by the specific volume?
No. At 14.7, you take the specific volume at the particular temperature (≥100C) and divide it into 300 liters (0.3 m^3) to get the kg.
 

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