(a) Explanation Write the expression for the pressure at state 2. p r 2 = ( p 2 p 1 ) p r 1 (I) Here, the pressure at state 1 is p 1 , the reduced pressure at state 2 is p r 2 , the pressure at state 2 is p 2 and the reduced pressure at state 1 is p r 1 . Write the expression for the pressure at state 4. p r 4 = ( p 4 p 3 ) p r 3 (II) Here, the pressure at state 3 is p 3 , the reduced pressure at state 4 is p r 4 , the pressure at state 4 is p 4 and the reduced pressure at state 3 is p r 3 . Write the expression for the mass flow rate. m ˙ = Q ˙ i n h 1 − h 4 (III) Here, the rate of the heat transfer is Q ˙ i n , the specific enthalpy at state 1 is h 1 , the specific enthalpy at state 4 is h 4 . 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 (IV) Here, the variables denote by x and y are temperature and specific enthalpy. Conclusion: Refer to table A-22E “Ideal gas properties of air” to obtain the specific enthalpy at temperature T 1 = 450 ° R as 107.51 Btu / lb by using interpolation method. Refer to table A-22E “Ideal gas properties of air” to obtain the specific enthalpy at temperature T = 440 ° R as 105.11 Btu / lb . Refer to table A-22E “Ideal gas properties of air” to obtain the specific enthalpy at temperature T = 460 ° R as 109.90 Btu / lb . Show the specific enthalpy at 440 °R and 460 °R as in below Table. Specific enthalpy kJ / kg Temperature °R 105.11 Btu / lb ( y 1 ) 440 °R ( x 1 ) y 2 450 °R ( x 2 ) 109.90 Btu / lb ( y 3 ) 460 °R ( x 3 ) Substitute 440 °R for x 1 , 450 °R for x 2 , 460 °R for x 3 , 105.11 Btu / lb for y 1 , and 109.90 Btu / lb for y 3 in Equation (IV). y 2 = { [ ( 109.90 Btu / lb − 105.11 Btu / lb ) ( 450 °R − 440 °R ) ] ( 460 °R − 440 °R ) + 105.11 Btu / lb } = ( 47.9 ) 20 Btu / lb + 105.11 Btu / lb = 2.395 Btu / lb + 105.11 Btu / lb ≈ 107.505 Btu / lb So, the saturated specific enthalpy is 107.505 Btu / lb . Refer to table A-22E “Ideal gas properties of air” to obtain the pressure ratio at specific enthalpy h 1 = 107.505 Btu / lb as 0.7345 . Substitute 7 for p 2 p 1 and 0.7345 for p r 1 in Equation (I). p r 2 = ( 7 ) ( 0.7345 ) = 5.1415 Refer to table A-22E “Ideal gas properties of air”. Obtain the properties given in below Table. Specific enthalpy kJ / kg Pressure ratio 186.94 Btu / lb ( y 1 ) 5.051 ( x 1 ) y 2 5.1415 ( x 2 ) 191.81 Btu / lb ( y 3 ) 5 (b) To determine The work input, per unit of air flow. (c) To determine The coefficient of the performance.

8th Edition

ISBN: 2818440116926

Author: MORAN

Publisher: WILEY CONS

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Chapter 10.7, Problem 46P

(a)

To determine

The mass flow rate of the refrigerator.

(b)

To determine

The work input, per unit of air flow.

(c)

To determine

The coefficient of the performance.

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Chapter 10.7, Problem 44P

Chapter 10.7, Problem 47P

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FUNDAMENTALS OF ENGINEERING THERMODYNAM

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