a)
The exit temperature
a)
Answer to Problem 105RP
The exit temperature is
Explanation of Solution
Write energy balance equation for a closed system of steam.
Here, temperature at inlet and outlet condition is
Write the expression for the dryness fraction at state 2
Here,
Write the expression of the internal energy at state 2
Write the expression of the entropy at state 2
Write the expression of the mass of steam
Here, initial volume of steam is
Write the expression of the mass of air
Here, initial temperature is
Write the expression of the amount of fan work done in 24 min.
Here, change in time is
Write the expression of energy balance equation for a closed system of air.
Here, amount of heat transfer injected to the steam radiator is
Conclusion:
From Table A-1, “molar mass, gas constant, and critical point properties”, Obtain the gas constant
From Table A-3, “properties of common liquids, solids, and foods”, Obtain the specific heat
From Table A-6E, “Superheated water”, at the pressure of
From to Table A-5, “saturated water – pressure table”, obtain the following properties at the pressure of
Substitute
Substitute 0.6376 for
Substitute 0.6376 for
Substitute
0.01388 kg for m,
Calculate the volume of air.
Substitute 283 K for
Substitute
Substitute 12.58 kJ for
Thus, the exit temperature is
b)
The entropy change of the steam.
b)
Answer to Problem 105RP
The entropy change of the steam is
Explanation of Solution
Write the expression the entropy change of the steam.
Conclusion:
Substitute 0.01388 kg for m,
Thus, the entropy change of the steam is
c)
The entropy change of the air
c)
Answer to Problem 105RP
The entropy change of the air is
Explanation of Solution
Write the expression for the entropy change of the air.
Conclusion:
Substitute 98.5 kg for
Thus, the entropy change of the air is
d)
The energy destroyed during the process
d)
Answer to Problem 105RP
The energy destroyed during the process is
Explanation of Solution
For a closed system, write the simplification rate form of the entropy balance for the room.
Here, entropy generation is
Calculate the energy destroyed during the process
Here, dead state temperature is
Conclusion:
Substitute
Substitute 283 K for
Thus, the energy destroyed during the process is
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Chapter 8 Solutions
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