(a) Explanation Write energy balance equation for a steady flow system in the expression of rate form. E ˙ in − E ˙ out = Δ E ˙ system ↗ 0 ( steady ) E ˙ in − E ˙ out = 0 m ˙ h 1 = W ˙ s , out + m ˙ h 2 s W ˙ s , out = m ˙ ( h 1 − h 2 s ) W ˙ s , out = m ˙ c p ( T 1 − T 2 s ) (I) Here, initial temperature is T 1 , final temperature for isentropic case is T 2 s , rate of energy transfer at inlet and outlet condition is E ˙ in and E ˙ out respectively, enthalpy at state 1 is h 1 , enthalpy at state 2 for isentropic case is h 2 s , rate of change in energy transfer of a system is Δ E ˙ system , mass flow rate of argon is m , and the power output of the isentropic turbine is W ˙ s , out . Calculate the value of T 2 s from isentropic relations. T 2 s = T 1 ( P 2 s P 1 ) ( k − 1 ) / k (II) Here, inlet pressure is P 1 , and exit pressure for isentropic case is P 2 s . Calculate the isentropic efficiency of the turbine ( η T ) . η T = W ˙ a , out W ˙ s , out (III) Here, power output of a turbine is W ˙ a , out . Conclusion: Obtain the gas constant ( ρ ) , specific heat ratio ( k ) , and specific heat ( c p ) of argon from the Table A-2E of “Ideal gas specific heats of various common gases” as, k = 1 (b) To determine The second law efficiency of the adiabatic turbine.

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Chapter 8.8, Problem 103RP

(a)

To determine

The isentropic efficiency of the adiabatic turbine.

(b)

To determine

The second law efficiency of the adiabatic turbine.

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Chapter 8.8, Problem 102RP

Chapter 8.8, Problem 104RP

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The isentropic efficiency of the adiabatic turbine.

Solution Summary: The author explains the isentropic efficiency of the adiabatic turbine and the energy balance equation for a steady flow system.

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