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 14.7, Problem 105P
To determine

The rate of entropy generation for this process.

Expert Solution & Answer
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Answer to Problem 105P

The rate of entropy generation for this process is 3.402×104Btu/sR_.

Explanation of Solution

Express the mass flow rate of dry air at state 1.

m˙a1=V˙1v1 (I)

Here, volume flow rate at state 1 is V˙1 and specific volume at state 1 is v1.

Express the mass flow rate of dry air at state 2.

m˙a2=V˙2v2 (II)

Here, volume flow rate at state 2 is V˙2 and specific volume at state 2 is v2.

Express the mass flow rate of dry air at state 3 from the conservation of mass.

m˙a3=m˙a1+m˙a2 (III)

Express enthalpy at state 3.

m˙a1m˙a2=h2h3h3h1 (IV)

Here, enthalpy at state 1 and 2 is h1andh2 respectively.

Express specific humidity at state 3.

m˙a1m˙a2=ω2ω3ω3ω1 (V)

Here, specific humidity at state 1 and 2 is ω1andω2 respectively.

Determine the entropy balance on the mixing chamber for water.

ΔS˙w=m˙a3ω3s3m˙a1ω1s1m˙a2ω2s2 (VI)

Determine the partial pressure of water vapour at state 1 for air steam.

Pvap,1=ϕ1×Pg1=ϕ1×Psat@100°F (VII)

Determine the partial pressure of dry air at state 1 for air steam.

Pa1=P1Pvap,1 (VIII)

Here, the pressure at the state 1 is P1.

Determine the partial pressure of water vapour at state 2 for air steam.

Pvap,2=ϕ2×Pg2=ϕ2×Psat@50°F (IX)

Determine the partial pressure of dry air at state 2 for air steam.

Pa2=P2Pvap,2 (X)

Here, the pressure at the state 2 is P2.

Determine the partial pressure of water vapour at state 3 for air steam.

Pvap,3=ϕ3×Pg3=ϕ3×Psat@86.7°C (XI)

Determine the partial pressure of dry air at state 3 for air steam.

Pa3=P3Pvap,3 (XII)

Here, the pressure at the state 3 is P3.

Determine the entropy balance on the mixing chamber for the dry air.

ΔS˙a=m˙a1(s3s1)+m˙a2(s3s2)=[m˙a1(cp×lnT3T1R×lnPa,3Pa,1)+m˙a2(cp×lnT3T2R×lnPa,3Pa,2)] (XIII)

Here, the coefficient of constant pressure is cp, the temperature at the state 3 is T3, the temperature at the state 1 is T1, the temperature at the state 2 is T2, and the universal gas constant is R.

Determine the rate of entropy generation.

S˙gen=ΔS˙a+ΔS˙w . (XIV)

Conclusion:

Refer Figure A-31E, “psychometric chart at 1 atm total pressure”, and write the properties corresponding to dry bulb temperature of 100°F and relative humidity of 90%.

h1=66.7Btu/lbmdryairω1=0.0386lbmH2O/lbmdryairv1=14.98ft3/lbmdryair

Here, initial enthalpy is h1 and initial specific humidity is ω1.

Refer Figure A-31E, “psychometric chart at 1 atm total pressure”, and write the properties corresponding to dry bulb temperature of 50°C and relative humidity of 30%.

h2=14.5Btu/lbmdryairω2=0.0023lbmH2O/lbmdryairv2=12.90ft3/lbmdryair

Here, enthalpy at state 2 is h2 and specific humidity at state 2 is ω2.

Refer Table A-4E, “saturated water-temperature table”, and write the entropy at state 1 and 2 at temperature of 100°Fand50°F.

sg1=sg@100°F=1.9819Btu/lbmR

sg2=sg@50°F=2.1256Btu/lbmR

Substitute 3ft3/s for ν˙1 and 14.98ft3/lbmdryair for v1 in Equation (I).

m˙a1=3ft3/s14.98ft3/lbmdryair=0.2002lbm/s

Substitute 1ft3/s for ν˙2 and 12.90ft3/lbmdryair for v2 in Equation (II).

m˙a2=1ft3/s12.90ft3/lbmdryair=0.07755lbm/s

Substitute 0.2002lbm/s for m˙a1 and 0.07755lbm/s for m˙a2 in Equation (III).

m˙a3=0.2002lbm/s+0.07755lbm/s=0.2778lbm/s

Substitute 0.2002lbm/s for m˙a1, 0.07755lbm/s for m˙a2, 14.5Btu/lbmdryair for h2 and 66.7Btu/lbmdryair for h1 in Equation (IV).

0.2002lbm/s0.07755lbm/s=14.5Btu/lbmdryairh3h366.7Btu/lbmdryair2.5815=14.5Btu/lbmdryairh3h366.7Btu/lbmdryairh3=52.1Btu/lbmdryair

Substitute 0.2002lbm/s for m˙a1, 0.07755lbm/s for m˙a2, 0.0023lbmH2O/lbmdryair for ω2 and 0.0386lbmH2O/lbmdryair for ω1 in Equation (V).

0.2002lbm/s0.07755lbm/s=0.0023lbmH2O/lbmdryairω3ω30.0386lbmH2O/lbmdryair2.5815=0.0023lbmH2O/lbmdryairω3ω30.0386lbmH2O/lbmdryairω3=0.0284lbmH2O/lbmdryair

Refer Figure A-31E, “psychometric chart at 1 atm total pressure”, and write the properties corresponding to ω3=0.0284lbmH2O/lbmdryair and h3=52.1Btu/lbmdryair.

T3=86.7°Fϕ3=1(100%)

Refer Table A-4E, “saturated water-temperature table”, and write the entropy at state 3 at temperature of 86.7°F using an interpolation method.

s3=sg@86.7°F (XV)

Here, entropy of saturation liquid at temperature of 86.7°F is sg@86.7°F.

Write the formula of interpolation method of two variables.

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

Here, the variables denote by x and y is temperature and specific entropy at state 3 respectively.

Show the specific entropy at state 3 corresponding to temperature as in Table (1).

Temperature

T(°F)

Specific entropy at state 3

s3@sg(Btu/lbmR)

85 (x1)2.0214 (y1)
86.7 (x2)(y2=?)
90 (x3)2.0079 (y3)

Substitute 80°F,86.7°Fand90°F for x1,x2andx3 respectively, 2.0214Btu/lbmR for y1 and 2.0079Btu/lbmR for y3 in Equation (XIV).

y2=(86.7°F85°F)(2.0079Btu/lbmR2.0214Btu/lbmR)(90°F85°F)+2.0214Btu/lbmR=2.0168Btu/lbmR=sg@86.7°F

Substitute 2.0168Btu/lbmR for sg@86.7°F in Equation (XV).

sg3=2.0168Btu/lbmR

Substitute 0.2002lbm/s for m˙a1, 0.07755lbm/s for m˙a2, 0.2778lbm/s for m˙a3, 0.0023lbmH2O/lbmdryair for ω2, 0.0386lbmH2O/lbmdryair for ω1, 0.0284lbmH2O/lbmdryair for ω3, 2.0168Btu/lbmR for sg3, 1.9819Btu/lbmR for sg1, and 2.1256Btu/lbmR for sg2 in Equation (VI).

ΔS˙w=[(0.2778lbm/s×0.0284lbmH2O/lbmdryair×2.0168Btu/lbmR)(0.2002lbm/s×0.0386lbmH2O/lbmdryair×1.9819Btu/lbmR)(0.07755lbm/s×0.0023lbmH2O/lbmdryair×2.1256Btu/lbmR)]=[(0.015912Btu/sR)(0.015316Btu/sR)(0.000379Btu/sR)]=0.000217Btu/sR

Substitute 0.90 for ϕ1 and 0.95052psia for Psat@100°F in Equation (VII).

Pvap,1=(0.90)×(0.95052psia)=0.8555psia

Substitute 1 atm for P1 and 0.8555psia for Pvap,1 in Equation (VIII).

Pa1=1atm(0.8555psia)=1atm×((14.696psia)1atm)(0.8555psia)=14.696psia0.8555psia=13.84psia

Substitute 0.30 for ϕ2 and 0.17812psia for Psat@50°F in Equation (IX).

Pvap,2=(0.30)×(0.17812psia)=0.0534psia

Substitute 1 atm for P2 and 0.0534psia for Pvap,2 in Equation (X).

Pa2=1atm(0.0534psia)=1atm×((14.696psia)1atm)(0.0534psia)=14.696psia0.0534psia=14.64psia

Substitute 1.0 for ϕ3 and 0.6298psia for Psat@86.7°C in Equation (XI).

Pvap,3=(1.0)×(0.6298psia)=0.6298psia

Substitute 1 atm for P3 and 0.6298psia for Pvap,3 in Equation (XII).

Pa3=1atm(0.6298psia)=1atm×((14.696psia)1atm)(0.6298psia)=14.696psia0.6298psia=14.07psia

Substitute 0.2002lbm/s for m˙a1, 0.07755lbm/s for m˙a2, 0.06855Btu/lbmR for cp, 100°F for T1, 50°F for T2, 86.7°C for T3, 0.287kJ/kgK for R, 14.64 psia for Pa2, 13.84psia for Pa1, and 14.07 psia for Pa3 in Equation (XIII).

ΔS˙a=[(0.2002lbm/s)((0.240Btu/lbmR)×ln86.7°C100°F(0.06855Btu/lbmR)×ln14.07psia13.84psia)+(0.07755lbm/s)((0.240Btu/lbmR)×ln86.7°C50°F(0.06855Btu/lbmR)×ln14.07psia14.64psia)]=[(0.2002lbm/s)((0.240Btu/lbmR)×ln86.7°C100°F+460(0.06855Btu/lbmR)×ln14.07psia13.84psia)+(0.07755lbm/s)((0.240Btu/lbmR)×ln86.7°C50°F+460(0.06855Btu/lbmR)×ln14.07psia14.64psia)]=(0.2002lbm/s)(0.006899Btu/lbm)+(0.07755lbm/s)(0.01940Btu/lbm)=0.0001233Btu/sR

Substitute 0.0001233Btu/sR for ΔS˙a and 0.0002169Btu/sR for ΔS˙w in Equation (XIV).

S˙gen=0.0001233Btu/sR+0.0002169Btu/sR=0.0003402Btu/sR3402×104Btu/sR

Thus, the rate of entropy generation for this process is 3.402×104Btu/sR_.

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Chapter 14 Solutions

Thermodynamics: An Engineering Approach

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