EBK THERMODYNAMICS: AN ENGINEERING APPR
EBK THERMODYNAMICS: AN ENGINEERING APPR
8th Edition
ISBN: 8220100257056
Author: CENGEL
Publisher: YUZU
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Chapter 5.5, Problem 178RP

A liquid R-134a bottle has an internal volume of 0.0015 m3. Initially it contains 0.55 kg of R-134a (saturated mixture) at 26°C. A valve is opened and R-134a vapor only (no liquid) is allowed to escape slowly such that temperature remains constant until the mass of R-134a remaining is 0.15 kg. Find the heat transfer with the surroundings that is needed to maintain the temperature and pressure of the R-134a constant.

Expert Solution & Answer
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To determine

The heat transfer with the surrounding that is needed to maintain the temperature and pressure of R-134a constant.

Answer to Problem 178RP

The heat transfer with the surrounding that is needed to maintain the temperature and pressure of R-134a constant is 72.8kJ.

Explanation of Solution

Write the equation of mass balance.

minme=Δmsystem (I)

Here, the inlet mass is min, the exit mass is me and the change in mass of the system is Δmsystem.

The change in mass of the system for the control volume is expressed as,

Δmsystem=(m2m1)cv

Here, the subscripts 1 and 2 indicates the initial and final states of the system.

Consider the given rigid container as the control volume.

Initially the container is filled with liquid refrigerant and the valve is in closed position, further no other mass is allowed to enter the container. Hence, the inlet mass is neglected i.e. min=0.

Rewrite the Equation (I) as follows.

0me=(m2m1)cvme=m1m2 (II)

Write the formula for initial specific volume (v1).

v1=νm1 (III)

Write the formula for final specific volume (v2).

v2=νm2 (IV)

Here, the volume is ν, the specific volume is v, the mass is m, and the subscript 1 indicates the initial state, the subscript 2 indicates the final state.

Write the energy balance equation.

EinEout=ΔEsystem{[Qin+Win+min(h+ke+pe)in][Qe+We+me(h+ke+pe)e]}=[m2(u+ke+pe)2m1(u+ke+pe)1]system (V)

Here, the heat transfer is Q, the work transfer is W, the enthalpy is h, the internal energy is u, the kinetic energy is ke, the potential energy is pe and the change in net energy of the system is ΔEsystem; the suffixes 1 and 2 indicates the inlet and outlet of the system.

The process is maintained at isothermal at the open condition of valve, there is no heat transfer while the mass leaves the container .i.e. Qe=0. There is no work transfer, i.e. (Win=We=0). Neglect the kinetic and potential energy changes i.e. (Δke=Δpe=0). There is no mass inlet for the rigid container, the inlet mass is neglected i.e. (min=0).

The Equation (V) reduced as follows.

Qinmehe=m2u2m1u1Qin=m2u2m1u1+mehe (VI)

At the initial state 1:

The rigid container consist of saturated mixture refrigerant at 26°C.

Refer Table A-11, “Saturated refrigerant-134a-Temperature table”.

Obtain the following corresponding to the temperature of 26°C.

vf,1=0.0008312m3/kgvg,1=0.030008m3/kguf,1=87.26kJ/kgufg,1=156.89kJ/kg

The quality of the refrigerant at state 1 is expressed as follows.

x1=v1vf,1vg,1vf,1 (VII)

The internal energy of the refrigerant at state 1 is expressed as follows.

u1=uf,1+x1ufg,1 (VIII)

At the final state (2):

When the valve is opened, the vapor refrigerant only allowed to escape and the temperature is kept constant.

The final temperature of the refrigerant is also 26°C.

Refer Table A-12, “Saturated refrigerant-134a-Temperature table”.

Obtain the following corresponding to the temperature of 26°C.

vf,2=0.0008312m3/kgvg,2=0.030008m3/kguf,2=87.26kJ/kgufg,2=156.89kJ/kg

The quality of the refrigerant at state 2 is expressed as follows.

x2=v2vf,2vg,2vf,2 (IX)

The internal energy of the refrigerant at state 2 is expressed as follows.

u2=uf,2+x2ufg,2 (X)

Conclusion:

Substitute 0.55kg for m1 and 0.15kg for m2 in Equation (II).

me=0.55kg0.15kg=0.40kg

Substitute 0.0015m3 for ν and 0.55kg for m1 in Equation (III).

v1=0.0015m30.55kg=0.002727m3/kg

Substitute 0.0015m3 for ν and 0.15kg for m2 in Equation (IV).

v2=0.0015m30.15kg=0.01m3/kg

Substitute 0.002727m3/kg for v1, 0.0008312m3/kg for vf,1, and 0.030008m3/kg for vg,1 in Equation (VII).

x1=0.002727m3/kg0.0008312m3/kg0.030008m3/kg0.0008312m3/kg=0.00189580.0291768=0.064976

Substitute 0.064976 for x1, 87.26kJ/kg for uf,1, and 156.89kJ/kg for ufg,1 in

Equation (VIII).

u1=87.26kJ/kg+(0.064976)(156.89kJ/kg)=87.26kJ/kg+10.194085kJ/kg=97.4541kJ/kg97.45kJ/kg

Substitute 0.01m3/kg for v2, 0.0008312m3/kg for vf,2, and 0.030008m3/kg for vg,2 in Equation (IX).

x2=0.01m3/kg0.0008312m3/kg0.030008m3/kg0.0008312m3/kg=0.00916880.0291768=0.31425

Substitute 0.31425 for x2, 87.26kJ/kg for uf,2, and 156.89kJ/kg for ufg,2 in

Equation (X).

u2=87.26kJ/kg+(0.31425)(156.89kJ/kg)=87.26kJ/kg+49.3027kJ/kg=136.5627kJ/kg136.56kJ/kg

Here, the temperature is kept constant until the final state and the vapor only exits the tank. Hence the exit enthalpy is expressed as follows.

he=hg@26°C

Refer Table A-12, “Saturated refrigerant-134a-Temperature table”.

The exit enthalpy (he) corresponding to the temperature of 26°C is 264.73kJ/kg.

Substitute 0.15kg for m2, 136.56kJ/kg for u2, 0.55kg for m1, 97.45kJ/kg for u1, 0.40kg for me, and 264.73kJ/kg for he in Equation (VI).

Qin=[(0.15kg)(136.56kJ/kg)(0.55kg)(97.45kJ/kg)+(0.40kg)(264.73kJ/kg)]=(20.48453.5975+105.892)kJ=72.7785kJ72.8kJ

Thus, the heat transfer with the surrounding that is needed to maintain the temperature and pressure of R-134a constant is 72.8kJ.

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Chapter 5 Solutions

EBK THERMODYNAMICS: AN ENGINEERING APPR

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