Answer:
Final temperature: 659.8ºC
Expansion work: 3*75=225 kJ
Internal energy change: 275 kJ
Explanation:
First, considering both initial and final states, write the energy balance:
[tex]U_{2}-U_{1}=Q-W[/tex]
Q is the only variable known. To determine the work, it is possible to consider the reversible process; the work done on a expansion reversible process may be calculated as:
[tex]dw=Pdv[/tex]
The pressure is constant, so: [tex]w=P(v_{2}-v_{1} )=0.5*100*1.5=75\frac{kJ}{kg}[/tex] (There is a multiplication by 100 due to the conversion of bar to kPa)
So, the internal energy change may be calculated from the energy balance (don't forget to multiply by the mass):
[tex]U_{2}-U_{1}=500-(3*75)=275kJ[/tex]
On the other hand, due to the low pressure the ideal gas law may be appropriate. The ideal gas law is written for both states:
[tex]P_{1}V_{1}=nRT_{1}[/tex]
[tex]P_{2}V_{2}=nRT_{2}\\V_{2}=2.5V_{1}\\P_{2}=P_{1}\\2.5P_{1}V_{1}=nRT_{2}[/tex]
Subtracting the first from the second:
[tex]1.5P_{1}V_{1}=nR(T_{2}-T_{1})[/tex]
Isolating [tex]T_{2}[/tex]:
[tex]T_{2}=T_{1}+\frac{1.5P_{1}V_{1}}{nR}[/tex]
Assuming that it is water steam, n=0.1666 kmol
[tex]V_{1}=\frac{nRT_{1}}{P_{1}}=\frac{8.314*0.1666*373.15}{500} =1.034m^{3}[/tex]
[tex]T_{2}=100+\frac{1.5*500*1.034}{0.1666*8.314}=659.76[/tex] ºC
