(a) Explanation The below figure shows the T − s diagram of the process. Figure-(1) Write the expression for the isentropic efficiency. η c = h 2 s − h 1 h 2 − h 1 (I) Here, the enthalpy at point 2s is h 2 s , the enthalpy at point 1 is h 1 , the enthalpy at point 2 is h 2 . Write the expression for enthalpy at point 4. h 4 = h f 4 + x 4 ( h g 4 − h f 4 ) (II) Here, the enthalpy of liquid at point 4 is h f 4 , the enthalpy of vapor at point 4 is h g 4 and the dryness fraction at point 4 is x 4 . Write the expression for entropy at point 4. s 4 = s f 4 + x 4 ( s g 4 − s f 4 ) (III) Here, the entropy of liquid at point 4 is s f 4 , the entropy of vapor at point 4 is s g 4 and the dryness fraction at point 4 is x 4 . Write the expression for compressor power. W ˙ = m ˙ ( h 2 − h 1 ) (IV) Conclusion: Refer table A-12E “Properties of superheated refrigerant R-134a vapor table” to obtain the specific enthalpy and the specific entropy at pressure p 1 = 10 lbf / in 2 and temperature T 1 = 0 ° F as h 1 = 102.94 Btu / lb and s 1 = 0.2391 Btu / lb ° R . Since the process 1-2s is a constant entropy process, so s 1 = s 2 s Refer to Table A-12E, “Properties of superheated refrigerant R-134a”,to obtain the specific enthalpy at the pressure 180 lbf / in 2 and entropy 0.2391 by using interpolation method of two variables. Write the formula of interpolation method of two variables. y 2 = ( x 2 − x 1 ) ( y 3 − y 1 ) ( x 3 − x 1 ) + y 1 (V) Here, the variables denote by x and y are entropy and enthalpy. Show the specific enthalpy at entropy at 285 K and 290 K as in Table (1). Entropy Btu / lb ° R specific enthalpy, Btu / lb 0.2355 Btu / lb ° R 128.77 Btu / lb 0.2441 Btu / lb ° R ? 0.2391 Btu / lb ° R 134.19 Btu / lb Substitute 0.2355 Btu / lb ° R for x 1 , 0.2441 Btu / lb ° R for x 2 , 0.2391 Btu / lb ° R for x 3 , 128.77 Btu / lb for y 1 , and 134.19 Btu / lb for y 3 in Equation (V). y 2 = ( 0.2441 Btu / lb ° R − 0.2355 Btu / lb ° R ) ( 134.19 Btu / lb − 128.77 Btu / lb ) ( 0.2391 Btu / lb ° R − 0.2355 Btu / lb ° R ) + 128.77 Btu / lb = ( 8.6 × 10 − 3 Btu / lb ° R ) ( 5.42 Btu / lb ) 0.0636 Btu / lb ° R + 128.77 Btu / lb = 0.73289 Btu / lb + 128.77 Btu / lb = 129.5028 Btu / lb So the specific enthalpy is 129.5028 Btu / lb . Substitute 0.83 for η c , 129.5028 Btu / lb for h 2 s , 102.94 Btu / lb for h 1 in Equation (I). 0.83 = 129.5028 Btu / lb − 102.94 Btu / lb h 2 − 102.94 Btu / lb 0.83 h 2 − 85.4402 Btu / lb = 26 (b) To determine The rate of heat transfer from the working fluid. (c) To determine The coefficient of performance of the cycle. (d) To determine The rate of entropy production in the compressor. (e) To determine The rate of exergy destruction.

Fundamentals of Engineering Thermodynamics, Binder Ready Version

8th Edition

ISBN: 9781118820445

Author: Michael J. Moran, Howard N. Shapiro, Daisie D. Boettner, Margaret B. Bailey

Publisher: WILEY

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Question

Chapter 10.7, Problem 16P

(a)

To determine

The compressor power.

(b)

To determine

The rate of heat transfer from the working fluid.

(c)

To determine

The coefficient of performance of the cycle.

(d)

To determine

The rate of entropy production in the compressor.

(e)

To determine

The rate of exergy destruction.

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Chapter 10.7, Problem 15P

Chapter 10.7, Problem 17P

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