Explanation Write the formula to calculate volume of the container ( V ) . m 1 = V v 1 (I) Here, initial mass of the refrigerant-134a in the container is m 1 and initial specific volume of the refrigerant-134a is v 1 . Write the formula to calculate final mass of the refrigerant-134a in the container ( m 2 ) . m 2 = V v 2 (II) Here, final specific volume of the refrigerant-134a is v 2 . Write the expression for the mass balance for the tank which acts as the system. m in − m out = Δ m system m e = m 1 − m 2 (III) Here, mass of the refrigerant-134a entering the system is m in , mass of the refrigerant-134a leaving the system is m out , change in mass of the system is Δ m system and mass at the exit of the container is m e . Write the expression for the entropy balance on the extended system. S in − S out + S gen = Δ S system − m e s e + S gen = Δ S tank − m e s e + S gen = ( m 2 s 2 − m 1 s 1 ) tank S gen = m 2 s 2 − m 1 s 1 + m e s e (IV) Here, entropy generation is S gen , change in entropy of the extended system is Δ S tank , net entropy at inlet condition is S in , net entropy at outlet condition is S out , initial specific entropy is s 2 , final specific entropy is s 1 and entropy leaving the tank is s e . Write the expression to calculate exergy destruction during the process ( X destroyed ) . X destroyed = T 0 S gen (V) Here, dead state temperature is T 0 . Conclusion: Refer Table A-11, “Saturated refrigerant-134a-Temperature table”, obtain the following properties of refrigerant-134a at the temperature of 30 ° C . v 1 = v f = 0 .0008421 m 3 / kg v 2 = v g = 0 .026648 m 3 / kg u 1 = u f = 92 .93 kJ / kg u 2 = u g = 241 .17 kJ / kg s 1 = s f = 0 .34792 kJ / kg ⋅ K s 2 = s e = s g = 0 .91897 kJ / kg ⋅ K h e = h g = 266 .71 kJ / kg Here, specific enthalpy of the refrigerant-134a at exit is h e , specific entropy of the refrigerant-134a at exit is u e , initial specific entropy of the refrigerant-134a is s 1 , final internal energy of the refrigerant-134a is s 2 , initial internal energy of the refrigerant-134a is u 1 , final internal energy of the refrigerant-134a is u 2 , specific volume of saturated liquid is v f , specific volume of saturated vapor is v g , internal energy of saturated liquid is u f , internal energy of saturated vapor is u g , specific entropy of saturated liquid is s f , specific entropy of saturated vapor is s g and specific enthalpy of saturated vapor is h g

9th Edition

ISBN: 9781259822674

Author: Yunus A. Cengel Dr., Michael A. Boles

Publisher: McGraw-Hill Education

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Chapter 8.8, Problem 74P

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The exergy destruction associated during the process.

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Chapter 8.8, Problem 73P

Chapter 8.8, Problem 75P

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The exergy destruction associated during the process.

Solution Summary: The author explains the exergy destruction associated during the process. Write the formula to calculate volume of the container.

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