CENGEL'S 9TH EDITION OF THERMODYNAMICS:
CENGEL'S 9TH EDITION OF THERMODYNAMICS:
9th Edition
ISBN: 9781260917055
Author: CENGEL
Publisher: MCG
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Chapter 12.6, Problem 101RP

An adiabatic 0.2-m3 storage tank that is initially evacuated is connected to a supply line that carries nitrogen at 225 K and 10 MPa. A valve is opened, and nitrogen flows into the tank from the supply line. The valve is closed when the pressure in the tank reaches 10 MPa. Determine the final temperature in the tank (a) treating nitrogen as an ideal gas, and (b) using generalized charts. Compare your results to the actual value of 293 K.

Chapter 12.6, Problem 101RP, An adiabatic 0.2-m3 storage tank that is initially evacuated is connected to a supply line that

FIGURE P12–101

(a)

Expert Solution
Check Mark
To determine

The final temperature in the tank by treating nitrogen as an ideal gas and compare the result to the actual value of 293K.

Answer to Problem 101RP

The final temperature in the tank by treating nitrogen as an ideal gas is 314.8K.

Explanation of Solution

Write the equation of mass balance.

minme=Δmsystem (I)

Here, the inlet mass is min, the exit mass is me and the change in mass of the system is Δmsystem.

The change in mass of the system for the control volume is expressed as,

Δmsystem=(m2m1)cv

Here, the suffixes 1 and 2 indicates the initial and final states of the system.

Consider the given insulated tank as the control volume.

The valve is closed when the pressure in tank reaches to 10MPa and the nitrogen is not allowed to exit i.e. me=0. And also the initially the storage tank is evacuated i.e. m1=0.

Rewrite the Equation (I) as follows.

min0=(m20)cvmin=m2 (II)

Write the energy balance equation.

EinEout=ΔEsystem{[Qin+Win+min(h+ke+pe)in][Qe+We+me(h+ke+pe)e]}=[m2(u+ke+pe)2m1(u+ke+pe)1]system (III)

Here, the heat transfer is Q, the work transfer is W, the enthalpy is h, the internal energy is u, the kinetic energy is ke, the potential energy is pe and the change in net energy of the system is ΔEsystem; the suffixes 1 and 2 indicates the initial and final states of the system.

Since the tank is adiabatic, there is no heat transfer i.e. (Qin=Qe=0), there is no work transfer, i.e. (Win=We=0). Neglect the kinetic and potential energy changes i.e. (Δke=Δpe=0). There is no exit for the tank, the exit mass is neglected i.e. (me=0). At initial state, the tank is evacuated i.e. (m1=0).

The Equation (III) reduced as follows.

minhin=m2u2 (IV)

Substitute m2 for min in Equation (IV).

m2hin=m2u2hin=u2 (V)

Express the Equation (V) in molar basis.

M(hin)=M(u2)hin¯=u2¯ (VI)

Here, the molar mass of nitrogen is M, the molar enthalpy is hin¯, and molar internal energy is u2¯.

Conclusion:

The inlet condition of the nitrogen is 225K and 10MPa.

While considering the nitrogen as the ideal gas, its enthalpy is solely depends on temperature.

Refer Table A-18, “Ideal-gas properties of nitrogen, N2 ”.

The molar enthalpy of nitrogen corresponding to the temperature of 225K is 6537kJ/kmol.

Refer Equation (VI).

hin¯=u2¯=6537kJ/kmol

The final temperature of the nitrogen is expressed as follows.

T2=T@u2¯=6537kJ/kmol

Refer Table A-18, “Ideal-gas properties of nitrogen, N2 ”.

The final temperature (T2) of nitrogen corresponding to the internal energy of 6537kJ/kmol is 314.8K.

Thus, the final temperature in the tank by treating nitrogen as an ideal gas is 314.8K.

The percentage error with the actual temperature value of 293K is expressed as follows.

%Errror=314.8K293K293K×100=0.0744×100=7.44%

The error associated is 7.44%.

(b)

Expert Solution
Check Mark
To determine

The final temperature in the tank by using generalized departure charts.

Answer to Problem 101RP

The final temperature in the tank by using generalized departure charts is 294.7K.

Explanation of Solution

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

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

Tcr=126.2KPcr=3.39MPa

The reduced pressure (PR,i) and temperature (TR,i) at inlet state is expressed as follows.

TR,i=TiTcr=225K126.2K=1.78

PR,i=PiPcr=10MPa3.39MPa=2.95

At inlet:

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

The enthalpy departure factor (Zh,i) corresponding the reduced pressure (PR,i) and reduced temperature (TR,i) is 0.9.

Write formula for enthalpy departure factor (Zh,i) at inlet condition in molar basis.

Zh,i=(h¯i,idealhi¯)T,PRuTcr (VII)

Here, the inlet molar enthalpy at ideal gas state is h¯i,ideal, the inlet molar enthalpy and normal state is hi¯, the universal gas constant is Ru, and the critical temperature is Tcr; The subscripts T,P indicates the correspondence of given temperature and pressure.

Rearrange the Equation (I) to obtain hi¯.

hi¯=h¯i,idealZh,iRuTcr (VIII)

Write the formula for molar enthalpy at final state

h2¯=h¯2,idealZh,2RuTcr (IX)

Write the formula for molar internal energy at final state.

u2¯=h2¯ZRuT2 (X)

Here, the compressibility factor is Z.

The universal gas constant (Ru) is 8.314kJ/kmolK.

Conclusion:

Refer part (a) answer for h¯i,ideal.

h¯i,ideal=6537kJ/kmol

Substitute 6537kJ/kmol for h¯i,ideal, 0.9 for Zh,i, 8.314kJ/kmolK for Ru, and 126.2K for Tcr in Equation (VIII).

hi¯=6537kJ/kmol(0.9)(8.314kJ/kmolK)(126.2K)=6537kJ/kmol944.3041kJ/kmol=5592.6958kJ/kmol5593kJ/kmol

Refer Equation (VI).

hin¯=u2¯=5593kJ/kmol

It is given that the actual final temperature of nitrogen is 293K and it is lies in the temperature band of 280K to 300K.

Consider the exit temperature (T2) as 280K and calculate the final internal energy.

The reduced pressure (PR,2) and temperature (TR,2) at inlet state is expressed as follows.

TR,2=T2Tcr=280K126.2K=2.22

PR,2=P2Pcr=10MPa3.39MPa=2.95

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

The enthalpy departure factor (Zh,2) corresponding the reduced pressure (PR,2) and reduced temperature (TR,2) is 0.55.

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

The compressibility factor (Z2) corresponding the reduced volume (vR2) and reduced temperature (TR2) is 0.98.

Refer Table A-18, “Ideal-gas properties of nitrogen, N2 ”.

The final molar enthalpy of nitrogen (h¯2,ideal) at ideal gas state corresponding to the temperature of 280K is 8141kJ/kmol.

Substitute 8141kJ/kmol for h¯2,ideal, 0.55 for Zh,2, 8.314kJ/kmolK for Ru, and 126.2K for Tcr in Equation (IX).

h2¯=8141kJ/kmol(0.55)(8.314kJ/kmolK)(126.2K)=8141kJ/kmol577.0747kJ/kmol=7563.9253kJ/kmol7564kJ/kmol

Substitute 7564kJ/kmol for h2¯, 0.98 for Z2, 8.314kJ/kmolK for Ru, and 280K for T2 in Equation (X).

u2¯=7564kJ/kmol(0.98)(8.314kJ/kmolK)(280K)=7564kJ/kmol2281.3616kJ/kmol=5282.6384kJ/kmol5283kJ/kmol

Consider the exit temperature (T2) as 300K and calculate the final internal energy.

The reduced pressure (PR,2) and temperature (TR,2) at inlet state is expressed as follows.

TR,2=T2Tcr=300K126.2K=2.38

PR,2=P2Pcr=10MPa3.39MPa=2.95

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

The enthalpy departure factor (Zh,2) corresponding the reduced pressure (PR,2) and reduced temperature (TR,2) is 0.50.

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

The compressibility factor (Z2) corresponding the reduced volume (vR2) and reduced temperature (TR2) is 1.0.

Refer Table A-18, “Ideal-gas properties of nitrogen, N2 ”.

The final molar enthalpy of nitrogen (h¯2,ideal) at ideal gas state corresponding to the temperature of 300K is 8723kJ/kmol.

Substitute 8723kJ/kmol for h¯2,ideal, 0.50 for Zh,2, 8.314kJ/kmolK for Ru, and 126.2K for Tcr in Equation (IX).

h2¯=8723kJ/kmol(0.50)(8.314kJ/kmolK)(126.2K)=8723kJ/kmol524.6134kJ/kmol=8198.3866kJ/kmol8198kJ/kmol

Substitute 8198kJ/kmol for h2¯, 1.0 for Z2, 8.314kJ/kmolK for Ru, and 300K for T2 in Equation (X).

u2¯=8198kJ/kmol(1.0)(8.314kJ/kmolK)(300K)=8198kJ/kmol2494.2kJ/kmol=5703.8kJ/kmol5704kJ/kmol

Express interpolation formula to determine the final temperature (T2) corresponding to the molar internal energy of 5593kJ/kmol.

5593kJ/kmolu2¯@280Ku2¯@300Ku2¯@280K=T2280K300280K

Substitute 5283kJ/kmol for u2¯@280K and 5704kJ/kmol for u2¯@300K.

5593kJ/kmol5283kJ/kmol5704kJ/kmol5283kJ/kmol=T2280K300280K310kJ/kmol421kJ/kmol=T2280K20KT2=20K(0.7363)+280KT2=294.7268K

T2294.7K

Thus, the final temperature in the tank by using generalized departure charts is 294.7K.

The percentage error with the actual temperature value of 293K is expressed as follows.

%Errror=294.7K293K293K×100=0.00580×100=0.58%

The error associated is 0.58%.

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Chapter 12 Solutions

CENGEL'S 9TH EDITION OF THERMODYNAMICS:

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