To determine The net heat transfer through the wall of the bottle and the entropy generation during filling process. Explanation Write the expression for the mass balance of the system. m i n − m o u t = Δ m s y s t e m ……. (I). Here, mass in is m i n , mass out is m o u t and change in mass is Δ m s y s t e m . Write the equation when bottle is evacuated initially. m 1 = 0 . Write the equation when air is allowed to fill the bottle. m i = m 2 Refer the Table A-2“Ideal gas properties of air” Obtain the below properties of air at temperature of 27 ° C . h i = 300.19 kJ / kg u 2 = 214.07 kJ / kg R = 0.2870 kJ / kg ⋅ K Calculate the mass of the air that entered bottle ( m 2 ) . m 2 = P 2 ν R T 2 m 2 = ( 95 kPa ) ( 0.050 m 3 ) ( 0.2870 kJ / kg ⋅ K ) ( 27 ° C ) = ( 95 kPa ) ( 0.050 m 3 ) ( 0.2870 kJ / kg ⋅ K ) ( 1 kPa ⋅ m 3 1 kJ ) ( 27 + 273 ) K = 0.05517 kg Write the expression for the energy balance equation for a closed system without air in the room. E i n − E o u t = Δ E s y s t e m ……. (II). Here, energy transfer into the control volume is E i n , energy transfer exit from the control volume is E o u t and change in internal energy of system is Δ E s y s t e m . Substitute E i n = Q i n + m i h i , E o u t = 0 and Δ E s y s t e m = Δ U in Equation (II). Q i n + m i h i − 0 = Δ U Q i n = − m i h i + ( m 2 u 2 − m 1 u 1 ) ……. (III). Here, heat transfer in is Q i n , mass of the air in the line is m i , line enthalpy is h i , initial mass of the air is m 1 , final mass of the air is m 2 , initial internal energy is u 1 , and final internal energy is u 2 . Substitute m 1 = 0 and m 2 = m i in Equation (III). Q i n = − m i h i + ( m i u 2 − ( 0 ) u 1 ) Q i n = m i ( u 2 − h i ) = ( 0

5th Edition

ISBN: 9780078027680

Author: Yunus A. Cengel Dr., Robert H. Turner, John M. Cimbala

Publisher: McGraw-Hill Education

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Chapter 8, Problem 191RQ

To determine

The net heat transfer through the wall of the bottle and the entropy generation during

filling process.

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Chapter 8, Problem 190RQ

Chapter 9, Problem 1P

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Chapter 8 Solutions

Fundamentals of Thermal-Fluid Sciences

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