THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<
THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<
9th Edition
ISBN: 9781266657610
Author: CENGEL
Publisher: MCG CUSTOM
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Chapter 14.7, Problem 134RP

An automobile air conditioner uses refrigerant-134a as the cooling fluid. The evaporator operates at 100 kPa gage and the condenser operates at 1.5 MPa gage. The compressor requires a power input of 6 kW and has an isentropic efficiency of 85 percent. Atmospheric air at 25°C and 60 percent relative humidity enters the evaporator and leaves at 8°C and 90 percent relative humidity. Determine the volume flow rate of the atmospheric air entering the evaporator of the air conditioner, in m3/min.

Expert Solution & Answer
Check Mark
To determine

The volume flow rate of the air at the inlet of the evaporator.

Answer to Problem 134RP

The volume flow rate of the air at the inlet of the evaporator is 20.5m3/min_.

Explanation of Solution

Express the mass flow rate of dry air at state 1.

m˙a1=V˙1v1 (I)

Here, volume flow rate at state 1 is V˙1 and specific volume at state 1 is v1.

Write the formula for mass flow rate of condensate water.

m˙w=m˙a1(ω1ω2) (II)

Here, specific humidity at state 1 and 2 is ω1andω2 respectively

Write the formula for an energy balance on the control volume.

m˙ah1=Q˙in+m˙ah2+m˙whw2 (III)

Here, the rate of heat absorbed by the R-134a is Q˙in, the enthalpy at the state of 2 is h2, the enthalpy of the state of 1 in condensate water is h1

Write the formula of the mass flow rate of the refrigerant.

W˙C=m˙RhR2,shR1ηC (IV)

Here, the mass flow rate of refrigerant is m˙R, the enthalpy of the refrigerant state 2 is hR2,s, the enthalpy of the state 1 in the refrigerant is hR1, and the efficiency of the condenser is ηC.

Write the formula for the rate of heat absorbed by the R-134ain the evaporator.

Q˙R,in=m˙R(hR1hR4) (V)

Here, the enthalpy of the state 4 in the refrigerant is hR4.

Conclusion:

Refer Figure A-31, “psychometric chart at 1 atm total pressure”, and write the properties corresponding to dry bulb pressure of 100kPa and relative humidity of 90%.

h1=55.88kJ/kgdryairω1=0.01206kgH2O/kgdryairv1=0.8724m3/kgdryairh2=23.31kJ/kgdryairω2=0.006064kgH2O/kgdryair

Substitute 0.8724m3/kg for v1 in Equation (I).

m˙a1=V˙1(0.8724m3/kg)

Substitute V˙1(0.8724m3/kg) for m˙a1, 0.01206kgH2O/kgdryair for ω1, and 0.006064kgH2O/kgdryair for ω2 in Equation (II).

m˙w=V˙1(0.8724m3/kg)×(0.01206kgH2O/kgdryair0.006064kgH2O/kgdryair)=V˙1(0.8724m3/kg)×(0.005996kgH2O/kgdryair)=0.006873V˙1

Refer Table A-4, “saturated water-temperature table”, and write the specific enthalpy of condensate water at state 2 at temperature of 8°C using an interpolation method.

hw2=hf@8°C (VI)

Here, entropy of saturation liquid at temperature of 8°C is hf@8°C.

Write the formula of interpolation method of two variables.

y2=(x2x1)(y3y1)(x3x1)+y1 (VII)

Here, the variables denote by x and y is temperature and specific enthalpy of condensate water at state 2 respectively.

Show the specific enthalpy of condensate water at state 2 corresponding to temperature as in Table (1).

Temperature

T(°C)

Specific enthalpy at state 2

h2@hf(kJ/kg)

5 (x1)21.02 (y1)
8 (x2)(y2=?)
10 (x3)42.022 (y3)

Substitute 5°C,8°Cand10°C for x1,x2andx3 respectively, 21.02kJ/kg for y1 and 42.022kJ/kg for y3 in Equation (VII).

y2=(8°C5°C)(42.022kJ/kg21.02kJ/kg)(10°C5°C)+21.02kJ/kg=33.6212kJ/kg=h2@hf(kJ/kg)

Substitute 33.6212kJ/kg for h2@hf(kJ/kg) in Equation (VI).

hw2=33.6212kJ/kg

Substitute V˙1(0.8724m3/kg) for m˙a1, 55.88kJ/kg for h1, 23.11kJ/kg for h2, 33.63kJ/kg for hw,2, and 0.006873V˙1 for m˙w in Equation (III).

V˙1(0.8724m3/kg)(55.88kJ/kg)=[Q˙R,in+V˙1(0.8724m3/kg)×(23.11kJ/kg)+(0.006873V˙1)(33.63kJ/kg)] (VIII)

From the Table A-12 “Saturated Refrigerant-134a-Pressure Table”, obtain the value of the specific enthalpy and entropy at the inlet of the compressor for isentropic process at 200 kPa of pressure and dryness fraction of 1 as

hR1=244.50kJ/kgsR1=0.93788kJ/kgK

Refer Table A-12 “Saturated Refrigerant-134a-Pressure Table”, and write the specific enthalpy at the exit of the compressor for isentropic process at 1600 kPa of pressure and entropy of 0.93788kJ/kgK using an interpolation method Equation (VII).

hR2,s=287.96kJ/kg

From the Table A-12 “Saturated Refrigerant-134a-Pressure Table”, obtain the value of the specific enthalpy at the inlet of the compressor for isentropic process at 1600 kPa of pressure as:

hR3=hf@1600kPa=135.96kJ/kg

Here, the specific enthalpy at the state 4 and 3 are equal in the refrigerant.

Substitute 6 KW for W˙C, 287.96kJ/kg for hR2,s, 244.50kJ/kg for hR1, and 0.85 for ηC in Equation (IV).

6KW=m˙R(287.96244.50)kJ/kg0.856KW=m˙R43.46kJ/kg0.85m˙R=0.1173kg/sm˙R=0.1173kg/s×(1kg/min60kg/s)

m˙R=7.041kg/min

Substitute 7.041kg/min for m˙R, 244.50kJ/kg for hR1, and 135.96kJ/kg for hR4 in Equation (V).

Q˙R,in=(7.041kg/min)×(244.50kJ/kg135.96kJ/kg)=(7.041kg/min)×(108.54kJ/kg)=764.2kJ/min

Substitute 764.2kJ/min for Q˙R,in in Equation (VIII).

V˙1(0.8724m3/kg)(55.88kJ/kg)=[(764.2kJ/min)+V˙1(0.8724m3/kg)×(23.11kJ/kg)+(0.006873V˙1)(33.63kJ/kg)]V˙1=20.5m3/min

Thus, the volume flow rate of the air at the inlet of the evaporator is 20.5m3/min_.

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Chapter 14 Solutions

THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<

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