(a) Explanation Write the mass balance equation for the transfer of refrigerant R-134a through supply line. m i = m 2 − m 1 (I) Here, mass of refrigerant entered into the tank is m i , final mass of refrigerant is m 2 , and the initial mass of refrigerant is m 1 . Write the expression to calculate the mass from the specific volume. m = V v (II) Here, volume of the refrigerant is V and the specific volume of the refrigerant is v . Write the energy balance equation for the transfer of R-134a through supply line. E in − E out = Δ E system m ˙ i h i − Q ˙ out = m ˙ 2 u 2 − m ˙ 1 u 1 (III) Here, energy transfer at inlet and outlet condition is E in and E out respectively, and change in energy transfer of a system is Δ E system , heat output is Q out , specific enthalpy of the refrigerant entered into the tank is h i , specific internal energy of the refrigerant initially in the tank is u 1 , and the specific internal energy of the refrigerant finally in the tank is u 2 . Write the expression to calculate the final mass of the refrigerant in the tank ( m 2 ) . m 2 = m f + m g m 2 = V f v f + V g v g (IV) Here, mass of the saturated liquid refrigerant is m f , mass of the saturated vapor is m g , volume of the saturated liquid is V f , volume of the saturated vapor is V g , specific volume of the saturated liquid is v f , and the specific volume of the saturated vapor is v g . Write the expression to calculate the final internal energy. m 2 u 2 = m f u f + m g u g (V) Here, specific internal energy of the saturated liquid is u f and the specific internal energy of the saturated vapor is u g . Write the expression to calculate the final entropy. m 2 s 2 = m f s f + m g s g (VI) Here, specific entropy of the saturated liquid is s f and the specific entropy of the saturated vapor is s g . Conclusion: From the Table A-12 of “Saturated R-134a: Pressure”, obtain the properties of refrigerant at initial saturated pressure of 1.0 MPa as, v 1 = v g = 0.020329 m 3 / kg u 1 = u g = 250.71 kJ / kg s 1 = s g = 0.91574 kJ / kg ⋅ K From the Table A-13 of “Superheated refrigerant: R-134a”, obtain the properties of refrigerant entered into the tank at pressure of 1.4 MPa and temperature of 60 ° C as, h i = 285.47 kJ / kg s i = 0.9389 kJ / kg ⋅ K Substitute 0.2 m 3 for V and 0.020329 m 3 / kg for v 1 in Equation (II). m 1 = 0.2 m 3 0.020329 m 3 / kg = 9.838 kg Substitute 0 (b) To determine The amount of exergy destroyed during the process.

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Chapter 8.8, Problem 83P

(a)

To determine

The amount of heat transfer for the process.

(b)

To determine

The amount of exergy destroyed during the process.

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Chapter 8.8, Problem 82P

Chapter 8.8, Problem 84P

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A rigid tank of 0.22-m volume initially contains saturated vapor refrigerant-134a at 1.2 MPa. The tank is connected by a valve to a supply line that carries refrigerant-134a at 1.6 MPa and 46 C. The valve is opened, and the refrigerant is allowed to enter the tank. The valve is closed when it is observed that the tank contains saturated liquid at 1.6 MPa. Determine (a) the mass of the refrigerant that has entered the tank and (b) the amount of heat transfer.

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A 0.2-m3 rigid tank initially contains saturated refrigerant-134a vapor at 1 MPa. The tank is connected by a valve to a supply line that carries refrigerant-134a at 1.4 MPa and 60°C. The valve is now opened, and the refrigerant is allowed to enter the tank. The valve is closed when one-half of the volume of the tank is filled with liquid and the rest with vapor at 1.2 MPa. The refrigerant exchanges heat during this process with the surroundings at 25°C. Determine the exergy destruction associated with this process.

Chapter 8 Solutions

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The amount of heat transfer for the process.

Solution Summary: The author explains the mass balance equation for the transfer of refrigerant R-134a through supply line.

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The amount of heat transfer for the process.

The amount of exergy destroyed during the process.

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Chapter 8 Solutions