Thermodynamics: An Engineering Approach
Thermodynamics: An Engineering Approach
8th Edition
ISBN: 9780073398174
Author: Yunus A. Cengel Dr., Michael A. Boles
Publisher: McGraw-Hill Education
Question
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Chapter 6.11, Problem 154RP
To determine

The maximum net power output.

Expert Solution & Answer
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Answer to Problem 154RP

The maximum net power output is W.max=(hA)HTH1+(hA)H(hA)L{1(TLTH)12}2

Explanation of Solution

Write the heat gain transfer rate equation (Q˙H).

Q˙H=(hA)H(THTH*) (I)

Here, heat transfer coefficient with heat gain transfer per unit area for hot body is (hA)H and temperature of hot reservoir is TH* or TH.

Write the heat loss transfer rate equation (Q˙L).

Q˙L=(hA)L(TLTL*) (II)

Here, heat transfer coefficient with heat loss transfer per unit area for hot body is (hA)L and temperature of cold reservoir is TL* or TL.

Write the work done equation

W˙=ηthQ˙H (III)

Here, efficiency of the heat engine is ηth.

Write the reversible cycle relation between the hot and cold temperature reservoir.

TH*TL*=Q˙HQ˙L (IV)

Write the temperature relation between the reservoirs.

TL*TH=TL*TH*TH*TH=r(1x) (V)

Here, variables are r and x.

Conclusion:

Substitute (hA)H(THTH*) for Q˙H and (1TL*TH*) for ηth in Equation (III).

W˙=(1TL*TH*)(hA)H(THTH*)=(1TL*TH*)(hA)H(1TH*TH)TH=(hA)HTH(1TL*TH*)(1TH*TH) (VI)

Substitute TL*TH* for r and 1TH*TH for x in Equation (VI).

W˙=(hA)HTH(1r)x

Substitute TL*TH* for r, (hA)H(THTH*) for Q˙H, and (hA)L(TLTL*) for Q˙L in Equation (V).

1r=(hA)H(THTH*)(hA)L(TLTL*)=(hA)HTH(1TH*TH)(hA)LTH(TL*THTLTH)

Substitute TL*TH* for r and 1TH*TH for x in Equation (IV).

1r=(hA)Hx(hA)L[r(1x)TLTH]

x=rTL/THr[(hA)H/(hA)L+1] (VII)

Substitute Equation (VII) in (IV).

W.(hA)HTH=(hA)HTH(1r)rTLTHr[(hA)H(hA)L+1] (VIII)

Taking the partial derivative W.r holding everything else constant and setting it equal to zero gives

r=TL*TH*=(TLTH)12 (IX)

Substitute Equation (IX) into (VIII).

W.max=(hA)HTH1+(hA)H(hA)L{1(TLTH)12}2

Thus, the maximum net power output is W.max=(hA)HTH1+(hA)H(hA)L{1(TLTH)12}2.

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Chapter 6 Solutions

Thermodynamics: An Engineering Approach

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