(a) Explanation Write the expression for mass balance across turbine. m ˙ 1 = m ˙ 2 + m ˙ 3 m ˙ 3 = m ˙ 1 − m ˙ 2 (I) Here, the mass flow rate at the inlet of turbine is m ˙ 1 , the mass flow rate at the exit of turbine is m ˙ 3 and the bled off mass flow rate is m ˙ 2 . Write the expression for energy balance across turbine. Q ˙ c v + m ˙ 1 h 1 = W ˙ c v + m ˙ 2 h 2 + m ˙ 3 h 3 Q ˙ c v = W ˙ c v + m ˙ 2 h 2 + m ˙ 3 h 3 − m ˙ 1 h 1 (II) Here, the rate of heat supplied to the turbine is Q ˙ c v , the rate of work done by the turbine is W ˙ c v , the specific enthalpy at the inlet is h 1 , the specific enthalpy at exit of turbine is h 3 and the specific enthalpy of bled steam is h 2 . Write the expression for specific enthalpy at exit of turbine. h 3 = h f + x ( h g − h f ) (III) Here, the specific enthalpy at exit is h 3 , the liquid specific enthalpy at exit is h f , the vapor specific enthalpy at exit is h g and the mole fraction is x . Conclusion: Substitute 10 5 lb / h for m ˙ 1 and 25 × 10 3 lb / h for m ˙ 2 in Equation (I). m ˙ 3 = 10 5 lb / h − 25 × 10 3 lb / h = 75 × 10 3 lb / h Refer to Table A-3E “Properties of Saturated Water (Liquid-Vapor): Pressure Table” to obtain values of liquid specific enthalpy as 94.02 Btu / lb and vapour specific enthalpy as 1116.1 Btu / lb . Substitute 94.02 Btu / lb for h f , 1116.1 Btu / lb for h g and 0.9 for x in Equation (III). h 3 = 94.02 Btu / lb + 0.9 ( 1116.1 Btu / lb − 94.02 Btu / lb ) = 94.02 Btu / lb + 0.9 ( 1022.08 Btu / lb ) = 94.02 Btu / lb + 919 (b) To determine The exergetic efficiency for turbine.

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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Chapter 7.7, Problem 103P

(a)

To determine

The rate of heat transfer between the turbine and its surrounding in Btu/h.

(b)

To determine

The exergetic efficiency for turbine.

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Chapter 7.7, Problem 102P

Chapter 7.7, Problem 104P

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The rate of heat transfer between the turbine and its surrounding in Btu / h .

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The rate of heat transfer between the turbine and its surrounding in Btu/h.

The exergetic efficiency for turbine.

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