(a) Explanation Write the formula to calculate change in enthalpy of air across the turbine ( Δ h ) . Δ h = c p ( T 2 − T 1 ) (I) Here, specific heat capacity of air is c p , temperatures of air at inlet and exit of the turbine are T 1 and T 2 respectively. Write the formula to calculate change in entropy of air across the turbine ( Δ s ) . Δ s = c p ln T 2 T 1 − R ln P 2 P 1 (II) Here, gas constant of air is R , pressures of air at inlet and exit of the turbine are P 1 and P 2 respectively. Write the formula to calculate actual power output of the turbine ( W ˙ a,out ) . W ˙ a,out = − m ˙ Δ h − Q ˙ out (III) Here, mass flow rate of air is m ˙ , rate at which the heat is lost from the turbine is Q ˙ out . Write the formula to calculate reversible power output of the turbine ( W ˙ rev,out ) . W ˙ rev,out = − m ˙ ( Δ h − T 0 Δ s ) (IV) Here, surrounding temperature is T 0 . Conclusion: Calculate the average temperature of air. T avg = 627 ° C + 527 ° C 2 = 577 ° C = ( 577 + 273 K ) = 850 K Refer Table A-2, " Ideal-gas specific heats of various common gases", obtain the following properties of air. R = 0.287 kJ / kg ⋅ K c p = c p @ 850 K = 1.11 kJ / kg ⋅ ° C Substitute 1.11 kJ / kg ⋅ ° C for c p , 527 ° C for T 2 and 627 ° C for T 1 in Equation (I). Δ h = ( 1.11 kJ / kg ⋅ ° C ) ( 527 ° C − 627 ° C ) = − 111 kJ / kg Substitute 0.287 kJ / kg ⋅ K for R , 1.11 kJ / kg ⋅ ° C for c p , 500 kPa for P 2 , 1200 kPa for P 1 , 527 ° C for T 2 and 627 ° C for T 1 in Equation (II) (b) To determine The exergy destroyed within the turbine. (c) To determine The second law efficiency of the turbine.

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Chapter 8.8, Problem 127RP

(a)

To determine

The actual and reversible power outputs of the turbine.

(b)

To determine

The exergy destroyed within the turbine.

(c)

To determine

The second law efficiency of the turbine.

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Chapter 8.8, Problem 126RP

Chapter 8.8, Problem 128RP

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The actual and reversible power outputs of the turbine.

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The actual and reversible power outputs of the turbine.

The exergy destroyed within the turbine.

The second law efficiency of the turbine.

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Chapter 8 Solutions