How to Determine Final Temperature and Enthalpy Change During Vaporization?

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To determine the final temperature and enthalpy change during the vaporization of water in a piston-cylinder setup, it's essential to use water property tables rather than the equation of state. The process is isobaric, meaning the pressure remains constant at 300 kPa until the water fully vaporizes. The correct approach involves finding the initial enthalpy from the tables and then calculating the enthalpy difference using the enthalpy of vaporization at the given pressure. The final temperature of 133.55 C and enthalpy change of 103,627 kJ can be confirmed through these tables. Utilizing the appropriate thermodynamic resources is crucial for accurate calculations in such scenarios.
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OK, I have a piston-cylinder with water.

V = 50L = 0.05 m^3
T = 25 C
P = 300 kPa
m = 49.85 kg
specific volume @ 25 C = 0.001003 m^3/kg

The water is heated to vaporization with pressure held constant. I need to determine the final temperature and the enthalpy change.

I know what the answers need to be (133.55 C and 103,627 kJ). On the temperature, I tried doing T = (PV/mR), using R = 0.4615 (kPa*m^3)/(kg*K), but i didn't get anywhere close.

On the enthalpy change part, I figured using m*h_fg, but that isn't right (I think).

Any ideas? Thanks a lot!
 
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physicsCU said:
OK, I have a piston-cylinder with water.

V = 50L = 0.05 m^3
T = 25 C
P = 300 kPa
m = 49.85 kg
specific volume @ 25 C = 0.001003 m^3/kg

The water is heated to vaporization with pressure held constant. I need to determine the final temperature and the enthalpy change.

I know what the answers need to be (133.55 C and 103,627 kJ). On the temperature, I tried doing T = (PV/mR), using R = 0.4615 (kPa*m^3)/(kg*K), but i didn't get anywhere close.

On the enthalpy change part, I figured using m*h_fg, but that isn't right (I think).

Any ideas? Thanks a lot!

1) Look at the water tables to see what enthalpy has the initial state,

2)The thermodynamic trajectory is an isobaric one until you have reached a 100% of water vapor inside cylinder. Look at a Mollier diagram or go to tables to localize the enthalpy of water vapor at 300Kpa. Then you have the enthalpy difference.

3) do not use the equation of state as you've done. It shows you didn't understand the problem at all. Imagine it physically: you are heating water to vaporize it with a free piston, do you really think volume is going to remain constant?
 
OK, I got the enthalpy difference, no problems.

I didn't realize my book had a pressure table, I found it there. Duh.

I neglected to mention that I looked at the v_fg values as well, and that didn't work. Sorry about that.

THANKS so much for your help. No wonder you are an engineer guru!
 
physicsCU said:
THANKS so much for your help. No wonder you are an engineer guru!

You're welcome!. Doubtless, there are another people who just wonder why the hell I am the PF eng. gurú.. :smile: To those...maybe they're right. :biggrin:
 

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