Calculating Work in an Expanding Gas: Isobaric vs. Isothermal Processes

AI Thread Summary
The discussion centers on the calculation of work done by an expanding gas, specifically helium, in a cylinder under varying pressures. The professor labeled the process as isobaric, which raised concerns since the gas pressure decreases from 200 kPa to atmospheric pressure during expansion. While the professor calculated work using W = Patm*ΔV, some participants argued that this simplification overlooks the non-constant pressure of the gas. Clarifications indicated that if the system is defined to include the surrounding atmosphere, the atmospheric pressure can be treated as constant for work calculations. Ultimately, the conversation highlights the nuances in defining systems and pressures in thermodynamic processes.
moogull
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Today in an engineering thermodynamics lecture, the professor gave an example of a gas doing work. We had a cylinder full of helium at a pressure of something like 200kPa absolute and the valve was opened so that the gas would flow out against the atmospheric pressure until the pressures were equal. Also the cylinder was assumed to be in thermal equilibrium with its surroundings so the temperature of the gas was equal to the temperature of the ambient air. However, the way he calculated the work perturbed me. He said that this was an isobaric process because the gas was expanding against a constant atmospheric pressure. I was under the assumption that an isobaric process means that the working fluid stays at constant pressure throughout the process which is not the case in this expansion. And in this case, the gas pressure is dropping as it leaves the cylinder.

The professor then proceeded to calculate the work as W = Patm*ΔV. But I don't think that is right and that simple.

Am I correct, or is the professor? Can someone please return me to sanity?
 
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moogull said:
He said that this was an isobaric process because the gas was expanding against a constant atmospheric pressure. I was under the assumption that an isobaric process means that the working fluid stays at constant pressure throughout the process which is not the case in this expansion. And in this case, the gas pressure is dropping as it leaves the cylinder.
You are right, the helium expands and its pressure decreases from 200kPa to atmospheric 100 kPa. Helium gas does not undergo isobaric process in the common sense of the word (atmosphere does).

moogull said:
The professor then proceeded to calculate the work as W = Patm*ΔV. But I don't think that is right and that simple.

Your professor is right this time - the work helium does on the atmosphere is indeed (approximately) W = Patm*ΔV, where ΔV is the volume of the helium gas outside the cylinder just after it escapes from it. After a while, the helium is heated by the atmosphere and expands even more and does further work, but this work is neglected in the above.
 
Thanks for the response Jano,

If the process is not isobaric, then why is the work not calculated using an integral and instead W = Patm*ΔV. I'm fairly certain he took the system as a control mass/closed system.
 
You can write the work as integral, but because the pressure of the atmosphere can be assumed constant during the process, the result is just ##P_{atm} \Delta V##.
 
Okay, so in this case, why is the pressure of the atmosphere the pressure used to calculate work and not the pressure of the working fluid?
 
What I mean to say is, why, since this is not an isobaric process, the work is calculated using a pressure that is assumed not to change?

edit: Looking at the atmosphere as the working fluid I agree that the work is defined P_atm*deltaV.
 
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moogull said:
What I mean to say is, why, since this is not an isobaric process, the work is calculated using a pressure that is assumed not to change?

edit: Looking at the atmosphere as the working fluid I agree that the work is defined P_atm*deltaV.
It depends on what you define as your system. If you define your system as just the gas that remains in the cylinder after equilibration, then that gas has done work on expelling the gas from the cylinder, and the pressure at the interface with the gas that it expelled was not at constant pressure.

If you define your system by surrounding all the helium that was originally inside the cylinder with an imaginary moving boundary, then, throughout this process, different parts of the helium were at different pressures. However, at the imaginary boundary with the surrounding atmospheric air, the pressure was constant (atmospheric). In the first law, you calculate the work done on the surroundings by calculating the integral of the pressure at the interface with the surroundings integrated over the volume change. (See my Blog on my PF home page.) So, in the case of this system, your professor was correct.


Chet
 
Hello

Is it possible then to calculate the same work looking only at the work of the expanding gas inside the cylinder ?

I assume one would have to use d(PV) and then a equation of state for the process.

Odd
 
Odd said:
Hello

Is it possible then to calculate the same work looking only at the work of the expanding gas inside the cylinder ?

I assume one would have to use d(PV) and then a equation of state for the process.

Odd
You would just solve it as an isothermal reversible expansion. The real irreversibility occurs within the valve, where the pressure drops from that inside the cylinder to 1 atm.

Chet
 
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