(a) Explanation Write the formula to calculate the isentropic efficiency of the compressor ( η C ) . η C = h 2 s − h 1 h 2 a − h 1 (I) Here, specific enthalpy at the isentropic exit of compressor is h 2 s , specific enthalpy at the actual exit of compressor is h 2 a , specific enthalpy at the inlet of the compressor is h 1 . Write the expression to calculate the mass from the specific volume. m = V v (II) Here, volume of the refrigerant is V and the specific volume of the refrigerant is v . Write the energy balance equation for the adiabatic compressor. E in − E out = Δ E system W ˙ a,in + m ˙ h 1 = m ˙ h 2 (III) Here, energy transfer at inlet and outlet condition is E in and E out respectively, and change in energy transfer of a system is Δ E system , and final specific enthalpy is h 2 . Conclusion: From the Table A-12E of “Saturated R-134a: Pressure”, obtain the properties of refrigerant at initial saturated pressure of 30 psia as, v 1 = v g = 1.5506 ft 3 / lbm h 1 = h g = 105.34 Btu / lbm s 1 = s g = 0.22386 Btu / lbm ⋅ R Here, specific volume at the inlet of the compressor is v 1 and the specific entropy at the inlet of the compressor is s 1 . From the Table A-13E of “Superheated refrigerant: R-134a”, obtain the specific enthalpy at the isentropic exit of compressor ( h 2 s ) for corresponding pressure of 70 psia and specific entropy of 0.22386 Btu / lbm ⋅ R as 112.83 Btu / lbm . Substitute 0.80 for η C , 112.83 Btu / lbm for h 2 s , and 105.34 Btu / lbm for h 1 in Equation (I) (b) To determine The second law efficiency of the compressor.

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Chapter 8.8, Problem 125RP

(a)

To determine

The actual power input required to the adiabatic compressor.

(b)

To determine

The second law efficiency of the compressor.

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Chapter 8.8, Problem 124RP

Chapter 8.8, Problem 126RP

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Problem 6 (Optional, extra 6 points) 150 mm 150 mm 120 mm 80 mm 60 mm PROBLEM 18.103 A 2.5 kg homogeneous disk of radius 80 mm rotates with an angular velocity ₁ with respect to arm ABC, which is welded to a shaft DCE rotating as shown at the constant rate w212 rad/s. Friction in the bearing at A causes ₁ to decrease at the rate of 15 rad/s². Determine the dynamic reactions at D and E at a time when ₁ has decreased to 50 rad/s. Answer: 5=-22.01 +26.8} N E=-21.2-5.20Ĵ N

Problem 1. Two uniform rods AB and CE, each of weight 3 lb and length 2 ft, are welded to each other at their midpoints. Knowing that this assembly has an angular velocity of constant magnitude c = 12 rad/s, determine: (1). the magnitude and direction of the angular momentum HD of the assembly about D. (2). the dynamic reactions (ignore mg) at the bearings at A and B. 9 in. 3 in. 03 9 in. 3 in. Answers: HD = 0.162 i +0.184 j slug-ft²/s HG = 2.21 k Ay =-1.1 lb; Az = 0; By = 1.1 lb; B₂ = 0.

Problem 5 (Optional, extra 6 points) A 6-lb homogeneous disk of radius 3 in. spins as shown at the constant rate w₁ = 60 rad/s. The disk is supported by the fork-ended rod AB, which is welded to the vertical shaft CBD. The system is at rest when a couple Mo= (0.25ft-lb)j is applied to the shaft for 2 s and then removed. Determine the dynamic reactions at C and D before and after the couple has been removed at 2 s. 4 in. C B Mo 5 in 4 in. Note: 2 rotating around CD induced by Mo is NOT constant before Mo is removed. and ₂ (two unknowns) are related by the equation: ₂ =0+ w₂t 3 in. Partial Answer (after Mo has been removed): C-7.81+7.43k lb D -7.81 7.43 lb

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The actual power input required to the adiabatic compressor.

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