Thermodynamics: An Engineering Approach
Thermodynamics: An Engineering Approach
9th Edition
ISBN: 9781260048766
Author: CENGEL
Publisher: MCG
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Chapter 14.7, Problem 132RP

Atmospheric air enters an air-conditioning system at 30°C and 70 percent relative humidity with a volume flow rate of 4 m3/min and is cooled to 20°C and 20 percent relative humidity at a pressure of 1 atm. The system uses refrigerant-134a as the cooling fluid that enters the cooling section at 350 kPa with a quality of 20 percent and leaves as a saturated vapor. Show the process on the psychrometric chart. What is the heat transfer from the air to the cooling coils, in kW? If any water is condensed from the air, how much water will be condensed from the atmospheric air per min? Determine the mass flow rate of the refrigerant, in kg/min.

Chapter 14.7, Problem 132RP, Atmospheric air enters an air-conditioning system at 30C and 70 percent relative humidity with a

FIGURE P14–132

Expert Solution & Answer
Check Mark
To determine

Show the process on the psychrometric chart; find the heat transfer from the air to the cooling coils, how much water will be condensed from the atmospheric air per min and the mass flow rate of the refrigerant.

Answer to Problem 132RP

The process on the psychrometric chart is shown below in Figure (1), the heat transfer from the air to the cooling coils is 3.727kW, the amount of water condensed from the atmospheric air per min is 0.07196kg/min and the mass flow rate of the refrigerant is

1.435kg/min.

Explanation of Solution

As the process is a steady flow and thus the mass flow rate of dry air remains constant during the entire process.

m˙a1=m˙a2=m˙a

Here, the mass flow rate of air at inlet is m˙a1, mass flow rate of dry air at exit is m˙a2 and mass flow rate of dry air is m˙a.

Express the mass flow rate of dry air.

m˙a=ν˙1v1 (I)

Here, volume flow rate at inlet is ν˙1 and specific volume at inlet is v1.

Express the mass flow rate of vapor at inlet.

m˙v1=ω1m˙a (II)

Here, specific humidity at state 1 is ω1.

Express the mass flow rate of vapor at exit.

m˙v2=ω2m˙a (III)

Here, specific humidity at state 2 is ω2.

Express the rate of condensation of water.

m˙w=m˙v1m˙v2 (IV)

Express the enthalpy of condensate water.

hw2=hf@20°C (V)

Here, enthalpy of saturation liquid at temperature of 20°C is hf@20°C.

Express the rate required heat transfer rate from the atmospheric air to the evaporator fluid from an energy balance on the control volume.

m˙ah1=Q˙out+m˙ah2+m˙whw2 (VI)

Here, enthalpy at state 1 and 2 is h1andh2 respectively, and the rate required heat transfer rate is Q˙out.

Express enthalpy of refrigerant at inlet.

hR1=(1xR1)hf@350kPa+xR1hg@350kPa (VII)

Here, quality of refrigerant at inlet is xR1, enthalpy of saturation liquid at pressure of 350kPa is hf@350kPa and the enthalpy of saturation vapor at pressure of 350kPa is hg@350kPa.

Express enthalpy of refrigerant at exit.

hR2=(1xR2)hf@350kPa+xR2hg@350kPa (VIII)

Here, quality of refrigerant at exit is xR2.

Express the mass flow rate of the refrigerant.

m˙R=Q˙outhR2hR1 (IX)

Here, enthalpy of refrigerant at inlet and exit is hR1andhR2 respectively.

Conclusion:

Show the psychrometric diagram as in Figure (1).

Thermodynamics: An Engineering Approach, Chapter 14.7, Problem 132RP

Hence, the psychrometric diagram is shown in Figure (1).

Refer Figure A-31, “psychometric chart at 1 atm total pressure”, and write the properties corresponding to dry bulb temperature of 30°C and relative humidity of 70%.

h1=78.24kJ/kgdryairω1=0.01880kgH2O/kgdryairν1=0.8847m3/kgdryair

Refer Figure A-31, “psychometric chart at 1 atm total pressure”, and write the properties corresponding to dry bulb temperature of 20°C and relative humidity of 20%.

h2=27.45kJ/kgdryairω2=0.002885kgH2O/kgdryair

Substitute 4m3/min for ν˙1 and 0.8847m3/kgdryair for ν1 in Equation (I).

m˙a=4m3/min0.8847m3/kgdryair=4.521kg/min

Substitute 4.521kg/min for m˙a and 0.01880kgH2O/kgdryair for ω1 in Equation (II).

m˙v1=(0.01880)(4.521kg/min)=0.0850kg/min

Substitute 4.521kg/min for m˙a and 0.002885kgH2O/kgdryair for ω2 in Equation (III).

m˙v2=(0.002885)(4.521kg/min)=0.01304kg/min

Substitute 0.0850kg/min for m˙v1 and 0.01304kg/min for m˙v2 in Equation (IV).

m˙w=0.0850kg/min0.01304kg/min=0.07196kg/min

Hence, the amount of water condensed from the atmospheric air per min is 0.07196kg/min.

Refer Table A-4, “saturated water-temperature table”, and write the enthalpy of condensate water at temperature of 20°C.

hw2=hf@20°C=83.91kJ/kg

Here, enthalpy of saturation liquid is hf.

Substitute 83.91kJ/kg for hf@20°C in Equation (V).

hw2=83.91kJ/kg

Substitute 4.521kg/min for m˙a, 78.24kJ/kgdryair for h1, 27.45kJ/kgdryair for h2, 0.07196kg/min for m˙w and 83.91kJ/kg for hw2 in Equation (VI).

(4.521kg/min)(78.24kJ/kg)=[Q˙out+(4.521kg/min)(27.45kJ/kg)+(0.07196kg/min)(83.91kJ/kg)]

Q˙out=223.6kJ/min[s60min]=3.727kJ/s[kW60kJ/s]=3.727kW

Hence, the heat transfer from the air to the cooling coils is 3.727kW.

Refer Table A-12, saturated refrigerant-134a-presure table”, and write enthalpy of saturation liquid at pressure of 350kPa using an interpolation method.

Write the formula of interpolation method of two variables.

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

Here, the variables denote by x and y pressure and enthalpy of saturation liquid respectively.

Show the enthalpy of saturation liquid corresponding to pressure as in Table (1).

Pressure

P(kPa)

Enthalpy of saturation liquid

hf(kJ/kg)

320 (x1)55.14 (y1)
350 (x2)(y2=?)
360 (x3)59.70 (y3)

Substitute 320kPa,350kPaand360kPa for x1,x2andx3 respectively, 55.14kJ/kg for y1 and 59.70kJ/kg for y3 in Equation (X).

y2=(350kPa320kPa)(59.70kJ/kg55.14kJ/kg)(360kPa320kPa)+55.14kJ/kg=58.56kJ/kg=hf@350kPa

Thus, the enthalpy of saturation liquid at pressure of 350kPa is,

hf@350kPa=58.56kJ/kg

Refer Table A-12, saturated refrigerant-134a-presure table”, and write enthalpy of saturation vapor at pressure of 350kPa using an interpolation method.

Show the enthalpy of saturation vapor corresponding to pressure as in Table (2).

Pressure

P(kPa)

Enthalpy of saturation liquid

hg(kJ/kg)

320 (x1)251.93 (y1)
350 (x2)(y2=?)
360 (x3)253.86 (y3)

Use excels and tabulates the values form Table (2) in Equation (X) to get,

hg@350kPa=253.3775kJ/kg

Substitute 0.20 for xR1, 58.56kJ/kg for hf@350kPa and 253.3775kJ/kg for hg@350kPa in Equation (VII).

hR1=(10.20)(58.56kJ/kg)+(0.20)(253.3775kJ/kg)=46.848kJ/kg+50.6755kJ/kg=97.52kJ/kg

Substitute 1 for xR2, 58.56kJ/kg for hf@350kPa and 253.3775kJ/kg for hg@350kPa in Equation (VIII).

hR2=(11)(58.56kJ/kg)+(1)(253.3775kJ/kg)=0+253.3775kJ/kg=253.3775kJ/kg

Substitute 223.6kJ/min for Q˙out, 253.3775kJ/kg for hR2, and 97.52kJ/kg for hR1 in Equation (IX).

m˙R=223.6kJ/min253.3775kJ/kg97.52kJ/kg=1.435kg/min

Hence, the mass flow rate of the refrigerant is 1.435kg/min.

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Chapter 14 Solutions

Thermodynamics: An Engineering Approach

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