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 73P

A 0.6-m3 rigid tank is filled with saturated liquid water at 135°C. A valve at the bottom of the tank is now opened, and one-half of the total mass is withdrawn from the tank in liquid form. Heat is transferred to water from a source of 210°C so that the temperature in the tank remains constant. Determine (a) the amount of heat transfer and (b) the reversible work and exergy destruction for this process. Assume the surroundings to be at 25°C and 100 kPa.

(a)

Expert Solution
Check Mark
To determine

The amount of heat transfer during the process.

Answer to Problem 73P

The amount of heat transfer during the process is 1115kJ.

Explanation of Solution

Write the expression for the mass balance for a tank which acts as a system.

minmout=Δmsystem

me=m1m2 (I)

Here, mass of water entering the system is min, mass of water leaving the system is mout, change in mass of the system is Δmsystem, initial mass in the tank is m1, final mass in the tank is m2 and mass at the exit is me.

Write the expression for the energy balance equation for a closed system.

EinEout=ΔEsystem (II)

Here, net energy transfer in to the control volume is Ein, net energy transfer exit from the control volume is Eout and change in internal energy of system is ΔEsystem.

For steady state, the change in internal energy of system is zero.

ΔEsystem=0

Substitute 0 for ΔEsystem in Equation (II).

EinEout=0Ein=EoutQin=mehe+m2u2m1u1 (III)

Here, amount of heat transfer during the process is Qin, specific enthalpy at exit is he, internal energy at exit is ue, initial internal energy is u1 and final internal energy is u2.

Write the formula to calculate initial mass in the tank (m1).

m1=Vv1 (IV)

Here, volume of the tank is V and initial specific volume of the water is v1.

Write the relation between the initial and final mass of the tank.

m2=12m1                                                                                                             (V)

Write the formula to calculate final mass in the tank (m2).

m2=Vv2 (VI)

Here, final specific volume of the water is v2.

Write the expression to calculate the quality at state 2 (x2).

v2=vf+x2(vgvf) (VII)

Here, specific volume of saturated liquid is vf and specific volume of saturated vapor is vf.

Write the expression to calculate final internal energy (u2).

u2=uf+x2ufg (VIII)

Here, internal energy of saturated liquid is uf, and internal energy saturated mixture is ufg.

Write the expression to calculate the final specific entropy (s2).

s2=sf+x2sfg (IX)

Here, specific entropy of saturated liquid is sf and specific entropy saturated mixture is sfg.

Conclusion:

Refer Table A-4, “Saturated water-Temperature table”, obtain the following properties of water at the temperature of 135°C.

v1=vf=0.001705m3/kgvg=0.58179m3/kgu1=uf=567.41kJ/kgufg=1977.3kJ/kgs1=sf=1.6872kJ/kgK

Refer Table A-4, “Saturated water-Temperature table”, obtain the following properties of water at the temperature of 135°C.

he=hf=567.75kJ/kgse=sf=1.6872kJ/kgKsfg=5.2901kJ/kgK

Substitute 0.6 m3 for V and 0.001705m3/kg for v1 in Equation (IV).

m1=0.6 m30.001705m3/kg=558.32 kg

Substitute 558.32 kg for m1 in Equation (V).

m2=12(558.32 kg)=276.16 kg

Substitute 558.32 kg for m1 and 276.16 kg for m2 in Equation (I).

me=558.32 kg276.16 kg=276.16 kg

Substitute 276.16 kg for m2 and 0.6 m3 for V in Equation (VI).

276.16 kg=0.6 m3v2v2=0.002149 m3/kg

Substitute 0.002149 m3/kg for v2,0.001705m3/kg for vf, 0.58179m3/kg for vg in Equation (VII).

0.002149 m3/kg=0.001705m3/kg+x2(0.58179m3/kg0.001705m3/kg)x2=0.001851

Substitute 567.41kJ/kg for uf, 0.001851 for x2, 1977.3kJ/kg for ufg in Equation (VIII).

u2=567.41kJ/kg+(0.001851)(1977.3kJ/kg)=571.01kJ/kg

Substitute 1.6872kJ/kgK for sf, 0.001851 for x2, 5.2901kJ/kgK for sfg in Equation (IX).

s2=1.6872kJ/kgK+(0.001851)(5.2901kJ/kgK)=1.6970kJ/kgK

Substitute 276.16 kg for me, 567.75kJ/kg for he, 276.16 kg for m2, 571.01kJ/kg for u2, 558.32 kg for m1 and 567.41kJ/kg for u1 in Equation (III).

Qin=[(276.16 kg)(567.75kJ/kg)+(276.16 kg)(571.01kJ/kg)(558.32 kg)(567.41kJ/kg)]=1115 kJ

Thus, the amount of heat transfer during the process is 1115kJ.

(b)

Expert Solution
Check Mark
To determine

The reversible work and exergy destruction during the process.

Answer to Problem 73P

The exergy destruction during the process is 126kJ.

The reversible work for the process is 126kJ.

Explanation of Solution

Write the expression for the entropy balance on the extended system.

SinSout+Sgen=ΔSsystemQinTb,inmese+Sgen=ΔStankQinTb,inmese+Sgen=(m2s2m1s1)tankSgen=m2s2m1s1+meseQinTb,in (X)

Here, entropy generation is Sgen, change in entropy of the extended system is ΔStank, net entropy at inlet condition is Sin, net entropy at outlet condition is Sout and entropy leaving the tank is se and base temperature is Tb,in

Write the expression to calculate exergy destruction during the process (Xdestroyed).

Xdestroyed=T0Sgen (XI)

Here, dead state temperature is T0.

For the given process, the actual work is zero, then the reversible work will be equal to exergy destruction.

Xdestroyed=Wrev,outWact,out

Wrev,out=Xdestroyed (XII)

Conclusion:

Substitute 276.16 kg for m2,1.6970kJ/kgK for s2, 558.32kg for m1,1.6872kJ/kgK for s1, 276.16 kg for me, 1.6872kJ/kgK for se, 1115 kJ for Qin, and 210°C for Tb,in in Equation (X).

Sgen=[(276.16 kg)(1.6970kJ/kgK)(558.32kg)(1.6872kJ/kgK)+(276.16 kg)(1.6872kJ/kgK)1115 kJ210°C][(276.16 kg)(1.6970kJ/kgK)(558.32kg)(1.6872kJ/kgK)+(276.16 kg)(1.6872kJ/kgK)1115 kJ(210+273) K]=0.42282kJ/K

Substitute 25°C for T0 and 0.42282kJ/K for Sgen in Equation (V).

Xdestroyed=(25°C)(0.42282kJ/K)=[(25+273)K](0.42282kJ/K)=126 kJ

Thus, the exergy destruction during the process is 126kJ.

Substitute 126kJ for Xdestroyed in Equation (XII).

Wrev,out=126kJ

Thus, the reversible work during the process is 126kJ.

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Chapter 8 Solutions

THERMODYNAMICS-SI ED. EBOOK >I<

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