Thermodynamics: An Engineering Approach
Thermodynamics: An Engineering Approach
9th Edition
ISBN: 9781259822674
Author: Yunus A. Cengel Dr., Michael A. Boles
Publisher: McGraw-Hill Education
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Chapter 13.3, Problem 72P

A piston–cylinder device contains 6 kg of H2 and 21 kg of N2 at 160 K and 5 MPa. Heat is now transferred to the device, and the mixture expands at constant pressure until the temperature rises to 200 K. Determine the heat transfer during this process by treating the mixture (a) as an ideal gas and (b) as a nonideal gas and using Amagat’s law.

Chapter 13.3, Problem 72P, A pistoncylinder device contains 6 kg of H2 and 21 kg of N2 at 160 K and 5 MPa. Heat is now

a)

Expert Solution
Check Mark
To determine

The heat transfer during the process by treating as an ideal gas.

Answer to Problem 72P

The heat transfer during the process as an ideal gas is 4273kJ.

Explanation of Solution

Write a closed system energy balance for the gas mixture.

EinEout=ΔE0(steady)Ein=EoutQinWb,out=ΔH

Qin=ΔHQin=ΔHH2+ΔHN2Qin=NH2(h¯2h¯1)H2+NN2(h¯2h¯1)N2 (I)

Here, input energy is Ein, output energy is Eout, change in energy of a system is ΔEsystem, specific amount of heat transfer into the closed system is Qin, and specific enthalpy at state 1 and 2 is h¯1andh¯2 and mole fraction of H2andN2 is yO2andyN2 respectively.

Write the expression to obtain the mole number of N2 (NN2).

NN2=mN2MN2 (II)

Here, molar mass of N2 is mN2 and molar mass of N2 is MN2.

Write the expression to obtain the mole number of He (NHe).

NHe=mHeMHe (III)

Conclusion:

Refer Table A-1, “Molar mass, gas constant, and critical point properties”, obtain the molar masses of N2 and H2 as 28.0kg/kmol and 2kg/kmol respectively.

Substitute 6kg for mH2 and 2kg/kmol for MH2 in Equation (II).

NH2=6kg2kg/kmol=3kmol

Substitute 21kg for mN2 and 28.0kg/kmol for MN2 in Equation (III).

NN2=21kg28.0kg/kmol=0.75kmol

From the Table of ideal gas for H2, write the value of h1@160K as 4535.4kJ/kmol and h2@200K as 5669.2kJ/kmol, ideal gas for N2, write the value of h1@160K as 4648kJ/kmol and h2@200K as 5810kJ/kmol.

Substitute 3kmol for NH2, 5669.2kJ/kmol for h¯2,H2, 4535.4kJ/kmol for h¯1,H2, 0.75kmol for NN2, 5810kJ/kmol for h¯2,N2, and 4648kJ/kmol for h¯1,N2 to find the heat transfer during the process as an ideal gas in Equation (I).

Qin,ideal=[3kmol(5669.2kJ/kmol4535.4kJ/kmol)+0.75kmol(5810kJ/kmol-4648kJ/kmol)]=4273kJ

Thus, the heat transfer during the process as an ideal gas is 4273kJ.

b)

Expert Solution
Check Mark
To determine

The heat transfer during the process by treating as non-ideal gas.

Answer to Problem 72P

The heat transfer during the process by treating as non-ideal gas is 4745kJ.

Explanation of Solution

Write the expression to obtain the initial reduced temperature of H2 (TR1,H2).

TR1,H2=Tm,1Tcr,H2 (IV)

Here, critical temperature of H2 is Tcr,H2.

Write the expression to obtain the initial and final reduced pressure of H2 (PR1,H2).

PR1,H2=PR2,H2=PmPcr,H2 (V)

Here, critical temperature of H2 is Pcr,H2.

Write the expression to obtain the final reduced temperature of H2 (TR2,H2).

TR2,H2=Tm,2Tcr,H2 (VI)

Here, critical temperature of H2 is Tcr,H2.

Write the expression to obtain the initial reduced temperature of N2 (TR1,N2).

TR1,N2=Tm,1Tcr,N2 (VII)

Here, critical temperature of N2 is Tcr,N2.

Write the expression to obtain the initial and final reduced pressure of N2 (PR1,N2).

PR1,N2=PR2,N2=PmPcr,N2 (VIII)

Here, critical temperature of N2 is Pcr,N2.

Write the expression to obtain the final reduced temperature of N2 (TR2,N2).

TR2,N2=Tm,2Tcr,N2 (IX)

Here, critical temperature of N2 is Tcr,N2.

Consider hydrogen as ideal gas

Write the expression for molar enthalpy difference of hydrogen (h¯2h¯1)H2.

(h¯2h¯1)H2=(h¯2h¯1)H2,ideal (X)

Write the expression for molar enthalpy difference of nitrogen.

(h¯2h¯1)N2=RuTcr(Zh2Zh1)+(h¯2h¯1)ideal (XI)

Conclusion:

Substitute 160 K for Tm,1 and 33.3 K for Tcr,H2 in Equation (IV).

TR1,H2=160K33.3K=4.805

Substitute 5 MPa for Pm and 1.30 MPa for Pcr,H2 in Equation (V).

PR,H2=5MPa1.30MPa=3.846

Substitute 200 K for Tm,2 and 33.3 K for Tcr,H2 in Equation (VI).

TR2,H2=200K33.3K=6.006

Refer Figure A-30, “Generalized entropy departure chart”, obtain the value of Zh1 and Zh2 for H2 as 0 and 0 by taking TR1,H2 as 4.805, PR1,H2 as 3.846, and TR2,H2 as 6.006.

Substitute 160 K for Tm,1 and 126.2 K for Tcr,N2 in Equation (VII).

TR1,N2=160K126.2K=1.268

Substitute 5 MPa for Pm and 3.39 MPa for Pcr,N2 in Equation (VIII).

PR,N2=5MPa3.39MPa=1.475

Substitute 200 K for Tm,2 and 126.2 K for Tcr,N2 in Equation (IX).

TR2,N2=200K126.2K=1.585

Refer Figure A-30, “Generalized entropy departure chart”, obtain the value of Zs1 and Zs2 for N2 as 0.8 and 0.4 by taking TR1,N2 as 1.268, PR1,N2 as 1.475 and TR2,N2 as 1.585.

Substitute 5669.2kJ/kmol for h¯2 and 4535.4kJ/kmol for h¯1 in Equation (X).

(h¯2h¯1)H2=(5669.2kJ/kmol4535.4kJ/kmol)=1133.8kJ/kmol

Substitute 8.314kPam3/kmolK for Ru , 126.2K for Tcr , 1.3 for Zh2, 0.7 for Zh1, 5810kJ/mol for h¯2 and 4648kJ/mol for h¯1 in Equation (XI).

(h¯2h¯1)N2=[(8.314kPam3/kmolK)(126.2K)(1.30.7)+(5810kJ/mol4648kJ/mol)]=1791.5kJ/mol

Substitute 3kmol for NH2, 5669.2kJ/kmol for (h¯2h¯1)N2, 4535.4kJ/kmol for (h¯2h¯1)H2 and 0.75kmol for NN2 in Equation (I).

Qin=[3kmol(1133.8kJ/kmol)+0.75kmol(1791.5kJ/kmol)]=4745kJ

Thus, the heat transfer during the process by treating as non-ideal gas is 4745kJ.

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Chapter 13 Solutions

Thermodynamics: An Engineering Approach

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