Explanation Write the expression for specific flow exergy. e f = ( h − h o ) − T o ( s − s o ) + V 2 2 + g z (I) Here, the specific flow exergy is e f , the specific entropy is s , the specific entropy at dead state is s o , the ambient temperature is T o , the velocity is V , the height from datum is z , the specific enthalpy is h and the specific enthalpy at dead state is h o . Write the expression for specific exergy. e = e f − v ( p − p o ) (II) Here, the specific exergy is e , the specific volume is v , the pressure is p and the pressure at dead state is p o . Conclusion: Refer to Table A-4E “Properties of Superheated Water Vapor” to obtain the value of specific volume as 1.898 ft 3 / lb , value of specific enthalpy as 1365.4 Btu / lb and value of specific entropy as 1.6562 Btu / lb ⋅ ° R for pressure of 350 lbf / in 2 and temperature of 700 ° F . At dead state condition, the water is in liquid form with a temperature of 70 ° F and pressure of 14.7 lbf / in 2 . Refer to Table A-2E “Properties of Saturated Water (Liquid-Vapor): Temperature Table” to obtain value of specific volume at dead state as 0.01605 ft 3 / lb , value of specific enthalpy at dead state as 38.09 Btu / lb and value of specific entropy at dead state as 0.07463 Btu / lb ⋅ ° R for pressure of 14.7 lbf / in 2 and temperature of 70 ° F . Substitute 1365.4 Btu / lb for h , 38.09 Btu / lb for h o , 1.6562 Btu / lb ⋅ ° R for s , 0.07463 Btu / lb ⋅ ° R for s o , 120 ft / s for V , 32.2 ft / s 2 for g and 80 ft for z in Equation (I). e f = [ ( 1365.4 Btu / lb − 38.09 Btu / lb ) − 70 ° F ( 1.6562 Btu / lb ⋅ ° R − 0.07463 Btu / lb ⋅ ° R ) + ( 120 ft / s ) 2 2 + ( 32

Fundamentals of Engineering Thermodynamics, Binder Ready Version

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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 51P

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The specific flow exergy in Btu/lb.

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