THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<
THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<
9th Edition
ISBN: 9781266657610
Author: CENGEL
Publisher: MCG CUSTOM
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Chapter 8.8, Problem 48P

A piston–cylinder device initially contains 1.4 kg of refrigerant-134a at 100 kPa and 20°C. Heat is now transferred to the refrigerant from a source at 150°C, and the piston, which is resting on a set of stops, starts moving when the pressure inside reaches 120 kPa. Heat transfer continues until the temperature reaches 80°C. Assuming the surroundings to be at 25°C and 100 kPa, determine (a) the work done, (b) the heat transfer, (c) the exergy destroyed, and (d) the second-law efficiency of this process.

FIGURE P8–48

Chapter 8.8, Problem 48P, A pistoncylinder device initially contains 1.4 kg of refrigerant-134a at 100 kPa and 20C. Heat is

(a)

Expert Solution
Check Mark
To determine

The work done.

Answer to Problem 48P

The work done is 0.497kJ.

Explanation of Solution

Express the boundary work done.

Wb,out=mP2(ν2ν1) (I)

Here, mass is m, final pressure is P2 and initial and final velocity is ν1andν2 respectively.

Conclusion:

Perform the unit conversion of initial pressure and final pressure from kPatoMPa.

P1=100kPa=100kPa[MPa1000kPa]=0.1MPa

P2=120kPa=120kPa[MPa1000kPa]=0.12MPa

Refer Table A-13, “superheated refrigerant-134a”, and write the properties corresponding to initial pressure of 0.1MPa and initial temperature (T1) of 20°C.

v1=0.23373m3/kgu1=248.81kJ/kgs1=1.0919kJ/kgK

Here, initial specific volume, internal energy and entropy is v1,u1ands1 respectively.

Refer Table A-13, “superheated refrigerant-134a”, and write the properties corresponding to final pressure of 0.12MPa and final temperature (T2) of 80°C using interpolation method.

Write the formula of interpolation method of two variables.

y2=(x2x1)(y3y1)(x3x1)+y1 (II)

Here, the variables denote by x and y is final pressure and final specific volume respectively.

Show the final specific volume at 0.10MPaand0.14MPa as in Table (1).

Final pressure

P2(MPa)

Final specific volume

v2(m3/kg)

0.10 (x1)0.28465 (y1)
0.12 (x2)(y2=?)
0.14 (x3)0.20242 (y3)

Substitute 0.10MPa,0.12MPaand0.14MPa for x1,x2andx3 respectively, 0.28465m3/kg for y1 and 0.20242m3/kg for y3 in Equation (II).

y2=(0.120.10)MPa(0.202420.28465)m3/kg(0.140.10)MPa+0.28465m3/kg=0.23669m3/kg=v2

Show the final specific internal energy at 0.10MPaand0.14MPa as in Table (2).

Final pressure

P2(MPa)

Final specific internal energy

u2(kJ/kg)

0.10 (x1)297.10 (y1)
0.12 (x2)(y2=?)
0.14 (x3)296.77 (y3)

Substitute 0.10MPa,0.12MPaand0.14MPa for x1,x2andx3 respectively, 297.10kJ/kg for y1 and 296.77kJ/kg for y3 in Equation (II).

y2=(0.120.10)MPa(296.77297.10)kJ/kg(0.140.10)MPa+297.10kJ/kg=296.94kJ/kg=u2

Show the final specific entropy at 0.10MPaand0.14MPa as in Table (3).

Final pressure

P2(MPa)

Final specific entropy

s2(kJ/kgK)

0.10 (x1)1.2573 (y1)
0.12 (x2)(y2=?)
0.14 (x3)1.2289 (y3)

Substitute 0.10MPa,0.12MPaand0.14MPa for x1,x2andx3 respectively, 1.2573kJ/kgK for y1 and 1.2289kJ/kgK for y3 in Equation (II).

y2=(0.120.10)MPa(1.22891.2573)kJ/kgK(0.140.10)MPa+1.2573kJ/kgK=1.2419kJ/kgK=s2

Thus, write the values obtained from interpolation method:

v2=0.23669m3/kgu2=296.94kJ/kgs2=1.2419kJ/kgK

Substitute 1.4kg for m, 120kPa for P2, 0.23669m3/kg for v2 and 0.23373m3/kg for v1 in Equation (I).

Wb,out=(1.4kg)(120kPa)(0.236690.23373)m3/kg=0.497kJ

Hence, the work done is 0.497kJ.

(b)

Expert Solution
Check Mark
To determine

The heat transfer.

Answer to Problem 48P

The heat transfer is 67.9kJ.

Explanation of Solution

Express heat transfer.

Qin=m(u2u1)+Wb,out (III)

Conclusion:

Substitute THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<, Chapter 8.8, Problem 48P , additional homework tip  1 for THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<, Chapter 8.8, Problem 48P , additional homework tip  2, 0.497kJ for Wb,out, 296.94kJ/kg for u2 and 248.81kJ/kg for u1 in Equation (III).

Qin=(1.4kg)(296.94kJ/kg248.81kJ/kg)+0.497kJ=67.9kJ

(c)

Expert Solution
Check Mark
To determine

The exergy destroyed.

Answer to Problem 48P

The exergy destroyed is 14.8kJ.

Explanation of Solution

Express the exergy destruction.

Xdestroyed=T0Sgen (IV)

Here, entropy generation is Sgen and surrounding temperature is T0.

Express the entropy generation by taking entropy balance on an extended system.

SinSout+Sgen=ΔSsystemQinTsource+Sgen=m(s2s1)Sgen=m(s2s1)QinTsource (V)

Here, net entropy transfer by heat and mass is SinSout, entropy generation is Sgen, change in entropy of system is ΔSsystem and source temperature is Tsource.

Conclusion:

Substitute 1.4kg for m, 1.2419kJ/kgK for s2, 1.0919kJ/kgK for s1, 67.9kJ for Qin and 150°C for Tsource in Equation (V).

Sgen=(1.4kg)(1.24191.0919)kJ/kgK67.9kJ150°C=(1.4kg)(0.15kJ/kgK)67.9kJ(150+273)K=(1.4kg)(0.15kJ/kgK)67.9kJ423K

Substitute (1.4kg)(0.15kJ/kgK)67.9kJ423K for Sgen and 25°C for T0 in Equation (IV).

Xdestroyed=(25°C)[(1.4kg)(0.15kJ/kgK)67.9kJ423K]=(25+273)K[(1.4kg)(0.15kJ/kgK)67.9kJ423K]=(298K)[(1.4kg)(0.15kJ/kgK)67.9kJ423K]=14.8kJ

Hence, the exergy destroyed is 14.8kJ.

(d)

Expert Solution
Check Mark
To determine

The second law efficiency of the process.

Answer to Problem 48P

The second law efficiency of the process is 26.2%.

Explanation of Solution

Express exergy expended.

Xexpended=ηth,revQin=[1TLTH]Qin (VI)

Here, efficiency for reversible cycle is ηth,rev, temperature of low source is TL and temperature of high source is TH.

Express the second law efficiency.

ηII=1XdestroyedXexpended×100% (VII)

Conclusion:

Substitute 25°C for TL and 150°C for TH and 67.9kJ for Qin in Equation (VI).

Xexpended=[125°C150°C](67.9kJ)=[1(25+273)K(150+273)K](67.9kJ)=[1298K423K](67.9kJ)=20.06kJ

Substitute 20.06kJ for Xexpended and 14.8kJ for Xdestroyed in Equation (VII).

ηII=114.8kJ20.06kJ×100%=0.262×100%=26.2%

Hence, the second law efficiency of the process is 26.2%.

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Chapter 8 Solutions

THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<

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