Thermodynamics: An Engineering Approach
Thermodynamics: An Engineering Approach
9th Edition
ISBN: 9781260048766
Author: CENGEL
Publisher: MCG
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Chapter 7.13, Problem 199RP
To determine

The total work required to fill the tank.

The total heat transferred from the air in the tank.

Expert Solution & Answer
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Answer to Problem 199RP

The total work required to fill the tank is 7.454×107Btu_.

The total heat transferred from the air in the tank is 4.990×107Btu_.

Explanation of Solution

Refer to Table A-2Ea, obtain the properties of air at room temperature.

Gasconstant,R=0.3704psiaft3lbmR

Constantpressurespecificheat,cp=0.240Btu/lbmR

Constantvolumespecificheat,cv=0.171Btu/lbmR

specificheatratio,k=1.4

Calculate the initial mass of air in the tank.

minitial=PinitialVRTinitial (I)

Here, pressure and temperature at initial state is PinitialandTinitial, and the tank volume is V.

Calculate the final mass of air in the tank.

mfinal=PfinalVRTfinal (II)

Here, pressure and temperature at final state is PfinalandTfinal respectively.

Since the compressor operates as an isentropic device, express the temperature at state 2.

T2=T1(P2P1)k1k

Here, specific heat ratio is k.

Express the conservation of mass applied to the tank.

dmdt=m˙2

Here, change of mass is dm, change in time is dt, and mass flow rate at state 2 is m˙2.

Write the equation of total power required to fill the tank using first law.

Q˙=d(mu)dth2dmdt (III)

Here, specific enthalpy at state 2 is h2.

Merge the ideal gas equation of state and constant specific heats in Equation (III).

Q˙=VcvRdPdtcpT2VRTdPdt (IV)

Use the temperature relation across the compressor and multiply by dt in Equation (IV).

Q˙dt=(VcvRdPdtcpT2VRTdPdt)dt=VcvRdPcpT2VRTdP (V)

Here, change in pressure is dP.

Integrate Equation (V) for initial and final states.

Q=VcvR(PfPi)k2k1cpVR[Pf(PfPi)k1kPi] (VI)

Here, pressures at initial and final states are Pi,andPf respectively.

Apply the first law to the tank and compressor.

(Q˙+W˙)dt=d(mu)h1dm (VII)

Here, specific enthalpy at initial state is h1 and

Integrate Equation (VII) to calculate the total heat transferred from the air in the tank.

Q+W=(mfufmiui)h1(mfmi)W=(mfufmiui)h1(mfmi)QW=Q(cpcv)T(mfmi) (VIII)

Here, specific internal energy at initial and final state is ui,uf, mass at initial and final state is mi,mf.

Conclusion:

Substitute 1 atm for Pinitial, 0.3704psiaft3lbmR for R, 1×106ft3 for V, and 70°F for Tinitial in Equation (I).

minitial=1atm(1×106ft3)(0.3704psiaft3lbmR)(70°F)=1atm×14.696psia1atm(1×106ft3)(0.3704psiaft3lbmR)(70+459.67)R=14.696psia(1×106ft3)(0.3704psiaft3lbmR)(530)R=74,860lbm

Substitute 10 atm for Pfinal, 0.3704psiaft3lbmR for R, 1×106ft3 for V, and 70°F for Tfinal in Equation (II).

mfinal=10atm(1×106ft3)(0.3704psiaft3lbmR)(70°F)=10atm×14.696psia1atm(1×106ft3)(0.3704psiaft3lbmR)(70+459.67)R=146.96psia(1×106ft3)(0.3704psiaft3lbmR)(530)R=748,600lbm

Substitute 1×106ft3 for V, 0.3704psiaft3lbmR for R, 10 atm for Pfinal, 1 atm for Pinitial, 0.171Btu/lbmR for cv, 0.240Btu/lbmR for cp, and 1.4 for k in Equation (VI).

Q={[(1×106ft3)0.171Btu/lbmR0.3704psiaft3lbmR(10atm1atm)]{(1.42(1.4)1)(0.240Btu/lbmR)1×106ft3(0.3704psiaft3lbmR)[10atm(10atm1atm)1.411.41atm]}}={[(1×106ft3)0.171Btu/lbmR0.3704psiaft3lbmR(10atm×14.696psia1atm1atm×14.696psia1atm)]{(1.42(1.4)1)(0.240Btu/lbmR)1×106ft3(0.3704psiaft3lbmR)[10atm×14.696psia1atm(10atm×14.696psia1atm1atm×14.696psia1atm)1.411.41atm×14.696psia1atm]}}=7.454×107Btu

Thus, the total work required to fill the tank is 7.454×107Btu_.

Substitute 70°F for T, 0.171Btu/lbmR for cv, 0.240Btu/lbmR for cp, 748,600lbm for mf, 74,860lbm for mi, and 7.454×107Btu for Q in Equation (VIII).

W=(7.454×107Btu)(0.240Btu/lbmR0.171Btu/lbmR)70°F(748,600lbm74,860lbm)=(7.454×107Btu)(0.240Btu/lbmR0.171Btu/lbmR)(70+459.67)R(748,600lbm74,860lbm)=4.990×107Btu

Thus, the total heat transferred from the air in the tank is 4.990×107Btu_.

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Chapter 7 Solutions

Thermodynamics: An Engineering Approach

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