Thermodynamics: An Engineering Approach ( 9th International Edition ) ISBN:9781260092684
Thermodynamics: An Engineering Approach ( 9th International Edition ) ISBN:9781260092684
9th Edition
ISBN: 9781260048667
Author: Yunus A. Cengel Dr.; Michael A. Boles
Publisher: McGraw-Hill Education
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Chapter 12.6, Problem 81P
To determine

The exergy destruction associate with the process.

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Answer to Problem 81P

The exergy destruction associate with the process is 23.3916kJ/kg.

Explanation of Solution

Write formula for enthalpy departure factor (Zh).

Zh=(hidealh)T,PRTcr (I)

Here, the enthalpy at ideal gas state is hideal, the enthalpy and normal state is h, the gas constant of propane is R, and the critical temperature is Tcr; The subscripts T,P indicates the correspondence of given temperature and pressure.

Rearrange the Equation (I) to obtain h.

h=hidealZhRTcr (II)

Refer Equation (II) express as two states of enthalpy difference (final – initial).

h2h1=(h2h1)ideal(Zh2Zh1)RTcr (III)

Consider the propane as the real gas and the express the equation of state.

Pν=ZRT (IV)

Here, the compressibility factor is Z.

Here the compressibility factor is,

Z=Zavg=Z1+Z22

Rewrite the Equation (IV) as follows.

Pν=ZavgRT

Consider the term ZavgRT as constant (C).

ZavgRT=C

The internal energy is expressed as follows.

u=hPν

Here, the enthalpy is h, the pressure is P, and the volume is ν.

Write the formula for change in internal energy.

u2u1=(h2h1)R(Z2T2Z1T1) (V)

While compression the boundary work is done on the system (piston-cylinder).

Write the formula for boundary work input.

wb,in=12Pdν=12Cνdν=C121νdν=Clnν2ν1

=(ZavgRT)lnZ2RT/P2Z1RT/P1=(ZavgRT)lnZ2/P2Z1/P1 (VI)

Here, the negative sign indicates the work done on the system.

Write the energy balance equation for the system (piston-cylinder).

EinEout=ΔEsystem(qin+wb,in)0=Δuqin+wb,in=u2u1 (VII)

Here, the net energy in is Ein, the net energy out is Eout and the change in net energy of the system is ΔEsystem.

Refer Table A-1, “Molar mass, gas constant, and critical-point properties”.

The critical temperature and pressure of propane gas is as follows.

Tcr=370KPcr=4.26MPa

The gas constant (R) of propane is 0.1885kJ/kgK.

The specific heat at constant pressure (cp) of propane is 1.6794kJ/kgK.

It is given that the propane is compressed isothermally. At ideal gas state the enthalpy is solely depends on temperature. Since, the process is isothermal (temperature is constant). Hence the change in enthalpy at ideal gas state becomes zero.

(h2h1)ideal=0

The reduced pressure (PR1) and temperature (TR1) at initial state is expressed as follows.

TR1=T1Tcr=(100+273)K370K=1.008

PR1=P1Pcr=1MPa4.26MPa=0.235

The reduced pressure (PR2) and temperature (TR2) at final state is expressed as follows.

TR2=T2Tcr=(100+273)K370K=1.008

PR2=P2Pcr=4MPa4.26MPa=0.939

Write the entropy balance equation for closed system.

Sin+SgenSout=ΔSsystem (VIII)

Here, the entropy input is Sin, the entropy output is Sout, the entropy generation in the system is Sgen and the change in entropy of system is ΔSsystem.

Rewrite the Equation (VII) as follows by substituting 0 for Sin, QoutTb,out for Sout and m(s2s1) for ΔSsystem, for this case.

SgenQoutTb,out=m(s2s1)Sgen=m(s2s1)+QoutTb,outmsgen=m(s2s1)+mqoutTb,outsgen=(s2s1)+qoutTb,out (IX)

Here, mass flow rate is m˙, amount of heat transfer is qout and surrounding temperature is Tb,out.

Write the formula for change in entropy ((s2s1)ideal) for ideal gas.

(s2s1)ideal=cplnT2T1RlnP2P1 (X)

Here, the gas constant is R, the specific heat at constant pressure is cp, the initial pressure is P1, the final pressure is P2, the final temperature is T2 and the initial temperature is T1.

Write the formula for change in entropy (s2s1) using generalized entropy departure chart relation.

s2s1=R(Zs1Zs2)+(s2s1)ideal (XI)

Here, the entropy departure factor is Zs.

Write the formula for exergy destruction associate with process.

xdestruction=Tb,outsgen

Substitute m(s2s1)+qoutTb,out for sgen.

xdestruction=Tb,out(s2s1+qoutTb,out) (XII)

At initial:

Refer Figure A-29, “Generalized enthalpy departure chart”.

The enthalpy departure factor (Zh1) corresponding the reduced pressure (PR1) and reduced temperature (TR1) is 0.28.

Refer Figure A-30, “Generalized entropy departure chart”.

The entropy departure factor (Zs1) corresponding the reduced pressure (PR1) and reduced temperature (TR1) is 0.21.

Refer Figure A-15, “Nelson–Obert generalized compressibility chart”.

The compressibility factor (Z1) corresponding the reduced pressure (PR1) and reduced temperature (TR1) is 0.92.

At final:

Refer Figure A-29, “Generalized enthalpy departure chart”.

The enthalpy departure factor (Zh2) corresponding the reduced pressure (PR2) and reduced temperature (TR2) is 1.8.

Refer Figure A-30, “Generalized entropy departure chart”.

The entropy departure factor (Zs2) corresponding the reduced pressure (PR2) and reduced temperature (TR2) is 1.5.

Refer Figure A-15, “Nelson–Obert generalized compressibility chart”.

The compressibility factor (Z2) corresponding the reduced pressure (PR2) and reduced temperature (TR2) is 0.50.

Conclusion:

The average compressibility factor is,

Zavg=0.92+0.502=1.422=0.71

Substitute 0 for (h2h1)ideal, 1.8 for Zh2, 0.28 for Zh1, 0.1885kJ/kgK for R, and 370K for Tcr in Equation (III).

h2h1={0[(1.80.28)(0.1885kJ/kgK)(370K)]}=0106.0124kJ/kg=106.0124kJ/kg

Substitute 106.0124kJ/kg for h2h1, 0.1885kJ/kgK for R, 0.5 for Z2, 373K for T2, 0.92 for Z1, and 373K for T1 in Equation (V).

u2u1={106.0124kJ/kg(0.1885kJ/kgK)[(0.5×373K)(0.92×373K)]}=106.0124kJ/kg+29.5304kJ/kg=76.482kJ/kg76.5kJ/kg

Substitute 0.71 for Zavg, 0.1885kJ/kgK for R, 373K for T, 0.5 for Z2, 4MPa for P2, 0.92 for Z1, and 1MPa for P1 in Equation (VI).

wb,in=(0.71)(0.1885kJ/kgK)(373K)ln(0.5/4MPa0.92/1MPa)=49.9204kJ/kg(1.9960)=99.6441kJ/kg99.6kJ/kg

Substitute 99.6kJ/kg for wb,in and 76.5kJ/kg for u2u1 in Equation (VII).

qin+99.6kJ/kg=76.5kJ/kgqin=76.5kJ/kg99.6kJ/kgqin=176.1kJ/kg

Here, the negative sign indicates the heat is transferred out from the system.

qout=176.1kJ/kg

Substitute 1.6794kJ/kgK for cp, 373K for T2, 373K for T1, 0.1885kJ/kgK for R, 4MPa for P2, and 1MPa for P1 in Equation (IX).

(s2s1)ideal=((1.6794kJ/kgK)ln(373K373K)(0.1885kJ/kgK)ln(4MPa1MPa))=(1.6794kJ/kgK)(0)0.2613kJ/kgK=0.2613kJ/kgK

Substitute 0.2613kJ/kgK for (s2s1)ideal, 0.21 for Zs2, 1.5 for Zs1 and 0.1885kJ/kgK for R in Equation (X).

s2s1=(0.1885kJ/kgK)(0.211.5)+(0.2613kJ/kgK)=0.2432kJ/kgK0.2613kJ/kgK=0.5044kJ/kgK0.504kJ/kgK

Substitute 30°C for Tb,out, 0.504kJ/kgK for s2s1, and 176.1kJ/kg for qout in Equation (XII).

xdestruction=(30°C)(0.504kJ/kgK+176.1kJ/kg30°C)=(30+273)K(0.504kJ/kgK+176.1kJ/kg(30+273)K)=303K(0.504kJ/kgK+0.5812kJ/kgK)=303K(0.0772kJ/kgK)

=23.3916kJ/kg

Thus, the exergy destruction associate with the process is 23.3916kJ/kg.

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Chapter 12 Solutions

Thermodynamics: An Engineering Approach ( 9th International Edition ) ISBN:9781260092684

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