THERMODYNAMICS-SI ED. EBOOK >I<
THERMODYNAMICS-SI ED. EBOOK >I<
9th Edition
ISBN: 9781307573022
Author: CENGEL
Publisher: MCG/CREATE
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Chapter 8.8, Problem 29P

Which is a more valuable resource for work production in a closed system −15 ft3 of air at 100 psia and 250°F or 20 ft3 of helium at 60 psia and 200°F? Take T0 = 77°F and P0 = 14.7 psia.

Expert Solution & Answer
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To determine

The more valuable resource for work production in a closed system; air or helium.

Answer to Problem 29P

The air has the more valuable resource for work production in a closed system.

Explanation of Solution

Express the mass in the system.

m=PνRT (I)

Here, mass is m, pressure is P, volume is ν, gas constant is R and temperature is T.

Express the entropy change between the given state and dead state.

ss0=cplnTT0RlnPP0 (II)

Here, entropy change between the given state and dead state is ss0, specific heat at constant pressure is cp, surrounding temperature is T0 and surrounding pressure is P0.

Express the specific volume at the given state.

v=RTP (III)

Express the specific volume at dead state.

v0=RT0P0 (IV)

Express the specific closed system exergy.

ϕ=uu0+P0(vv0)T0(ss0)=cv(TT0)+P0(vv0)T0(ss0) (V)

Here, specific internal energy is u, specific internal energy at dead state is u0 and specific heat at constant volume is cv.

Express the total exergy available for the production of work.

Φ=mϕ (VI)

Here, mass is m.

Conclusion:

Solve for AIR:

Refer Table A-1E, “molar mass, gas constant and critical point properties”, and write the gas constant of air.

R=0.06855Btu/lbmR=0.3704psiaft3/lbmR

Refer Table A-2E, “ideal gas specific heats of various common gases”, and write the properties of air.

cp=0.240Btu/lbmRcv=0.171Btu/lbmRk=1.4

Substitute 100psia for P, 15ft3 for ν, 0.3704psiaft3/lbmR for R and 250°F for T in Equation (I).

m=(100psia)(15ft3)(0.3704psiaft3/lbmR)(250°F)=(100psia)(15ft3)(0.3704psiaft3/lbmR)[(250+460)R]=(100psia)(15ft3)(0.3704psiaft3/lbmR)(710R)=5.704lbm

Substitute 0.240Btu/lbmR for cp, 250°F for T, 77°F for T0, 0.06855Btu/lbmR for R, 100psia for P and 14.7psia for P0 in Equation (II).

ss0=(0.240Btu/lbmR)[ln250°F77°F](0.06855Btu/lbmR)[ln100psia14.7psia]=(0.240Btu/lbmR){[ln(250+460)R(77+460)R](0.06855Btu/lbmR)[ln100psia14.7psia]}=(0.240Btu/lbmR)[ln710R537R](0.06855Btu/lbmR)[ln100psia14.7psia]=0.06441Btu/lbmR

Substitute 0.3704psiaft3/lbmR for R, 250°F for T, and 100psia for P in Equation (III).

v=(0.3704psiaft3/lbmR)(250°F)100psia=(0.3704psiaft3/lbmR)(250+460)R100psia=(0.3704psiaft3/lbmR)(710R)100psia=2.630ft3/lbm

Substitute 0.3704psiaft3/lbmR for R, 77°F for T0, and 14.7psia for P0 in Equation (IV).

v0=(0.3704psiaft3/lbmR)(77°F)14.7psia=(0.3704psiaft3/lbmR)(77+460)R14.7psia=(0.3704psiaft3/lbmR)(537R)14.7psia=13.53ft3/lbm

Substitute 0.171Btu/lbmR for cv, 250°F for T, 77°F for T0, 14.7psia for P0, 2.630ft3/lbm for v, 13.53ft3/lbm for v0, and 0.06441Btu/lbmR for ss0 in Equation (V).

ϕ={(0.171Btu/lbmR)(250°F77°F)+(14.7psia)[(2.63013.53)ft3/lbm]77°F(0.06441Btu/lbmR)}={(0.171Btu/lbmR)(710R537R)+(14.7psia)[(2.63013.53)ft3/lbm](537R)(0.06441Btu/lbmR)}=34.52Btu/lbm

Substitute 34.52Btu/lbm for ϕ and 5.704lbm for m in Equation (VI).

Φ=(5.704lbm)(34.52Btu/lbm)=197Btu (VII)

Solve for HELIUM:

Refer Table A-1E, “molar mass, gas constant and critical point properties”, and write the gas constant of helium.

R=0.4961Btu/lbmR=2.6809psiaft3/lbmR

Refer Table A-2E, “ideal gas specific heats of various common gases”, and write the properties of helium.

cp=1.25Btu/lbmRcv=0.753Btu/lbmRk=1.667

Substitute 60psia for P, 20ft3 for ν, 2.6809psiaft3/lbmR for R and 200°F for T in Equation (I).

m=(60psia)(20ft3)(2.6809psiaft3/lbmR)(200°F)=(60psia)(20ft3)(2.6809psiaft3/lbmR)[(200+460)R]=(60psia)(20ft3)(2.6809psiaft3/lbmR)(660R)=0.6782lbm

Substitute 1.25Btu/lbmR for cp, 200°F for T, 77°F for T0, 0.4961Btu/lbmR for R, 60psia for P and 14.7psia for P0 in Equation (II).

ss0=(1.25Btu/lbmR)[ln200°F77°F](0.4961Btu/lbmR)[ln60psia14.7psia]=(1.25Btu/lbmR){[ln(200+460)R(77+460)R](0.4961Btu/lbmR)[ln60psia14.7psia]}=(1.25Btu/lbmR)[ln660R537R](0.4961Btu/lbmR)[ln60psia14.7psia]=0.4400Btu/lbmR

Substitute 2.6809psiaft3/lbmR for R, 200°F for T, and 60psia for P in Equation (III).

v=(2.6809psiaft3/lbmR)(200°F)60psia=(2.6809psiaft3/lbmR)(200+460)R60psia=(2.6809psiaft3/lbmR)(660R)60psia=29.49ft3/lbm

Substitute 2.6809psiaft3/lbmR for R, 77°F for T0, and 14.7psia for P0 in Equation (IV).

v0=(2.6809psiaft3/lbmR)(77°F)14.7psia=(2.6809psiaft3/lbmR)(77+460)R14.7psia=(2.6809psiaft3/lbmR)(537R)14.7psia=97.93ft3/lbm

Substitute 0.753Btu/lbmR for cv, 200°F for T, 77°F for T0, 14.7psia for P0, 29.49ft3/lbm for v, 97.93ft3/lbm for v0, and 0.4400Btu/lbmR for ss0 in Equation (V).

ϕ={(0.753Btu/lbmR)(200°F77°F)+(14.7psia)[(29.4997.93)ft3/lbm]77°F(0.4400Btu/lbmR)}={(0.753Btu/lbmR)(660R537R)+(14.7psia)[(29.4997.93)ft3/lbm]Btu5.404psiaft3(537R)(0.4400Btu/lbmR)}=142.7Btu/lbm

Substitute 142.7Btu/lbm for ϕ and 0.6782lbm for m in Equation (VI).

Φ=(0.6782lbm)(142.7Btu/lbm)=96.8Btu (VIII)

On comparing the total exergy available for the potential of work from Equations (VII) and (VIII), it is obtained that air has more potential.

air>heliumΦ=197Btu>Φ=96.8Btu

Hence, the air has the more valuable resource for work production in a closed system.

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Chapter 8 Solutions

THERMODYNAMICS-SI ED. EBOOK >I<

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