Thermodynamics: An Engineering Approach
Thermodynamics: An Engineering Approach
9th Edition
ISBN: 9781259822674
Author: Yunus A. Cengel Dr., Michael A. Boles
Publisher: McGraw-Hill Education
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Chapter 14.7, Problem 79P

Air enters a 40-cm-diameter cooling section at 1 atm, 32°C, and 70 percent relative humidity at 120 m/min. The air is cooled by passing it over a cooling coil through which cold water flows. The water experiences a temperature rise of 6°C. The air leaves the cooling section saturated at 20°C. Determine (a) the rate of heat transfer, (b) the mass flow rate of the water, and (c) the exit velocity of the airstream.

FIGURE P14–79

Chapter 14.7, Problem 79P, Air enters a 40-cm-diameter cooling section at 1 atm, 32C, and 70 percent relative humidity at 120

(a)

Expert Solution
Check Mark
To determine

The rate of heat transfer.

Answer to Problem 79P

The rate of heat transfer is 478.7kJ/min.

Explanation of Solution

Express the dew point temperature of the incoming air at a temperature of 32°C.

Tdp=Tsat@(ϕ1×Psat@32°C) (I)

Here, the saturation pressure at temperature of 32°C is Psat@32°C and initial specific humidity is ϕ1.

Express initial volume rate of air.

ν˙1=V1A1=V1[πD24] (II)

Here, initial volume and area is V1andA1 respectively, and diameter is D.

Express the mass flow rate of air at inlet.

m˙a1=ν˙1v1 (III)

Here, initial specific volume is v1.

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

Express water mass balance to the combined cooling to obtain the mass flow rate of water.

m˙w,i=m˙w,em˙a1ω1=m˙a2ω2+m˙wm˙w=m˙a1(ω1ω2) (IV)

Here, mass flow rate of water at inlet and exit is m˙w,iandm˙w,e respectively, specific humidity at state 1 and 2 is ω1andω2 respectively and mass flow rate of water is m˙w.

Express the cooling rate when the condensate leaves the system by applying an energy balance on the humidifying section.

E˙inE˙out=ΔE˙systemE˙inE˙out=0E˙in=E˙outm˙ihi=Q˙out+m˙ehe

Q˙out=m˙a1h1(m˙a2h2+m˙whw)=m˙a1(h1h2)m˙whw (V)

Here, rate of heat rejected or cooling rate when the condensate leaves the system is Q˙out, the rate of total energy entering the system is E˙in, the rate of total energy leaving the system is E˙out, the rate of change in the total energy of the system is ΔE˙system, initial and exit mass flow rate is m˙iandm˙e respectively, enthalpy at inlet and exit is hiandhe respectively, enthalpy at state 1 and 2 is h1andh2 respectively, and enthalpy of water is hw.

Conclusion:

Refer Table A-4, “saturated water-temperature table”, and write saturation pressure at temperature of 32°C using an interpolation method.

Write the formula of interpolation method of two variables.

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

Here, the variables denote by x and y is temperature and saturation pressure respectively.

Show the saturation pressure corresponding to temperature as in Table (1).

Temperature

T(°C)

Saturation pressure

Psat(kPa)

30 (x1)4.2469 (y1)
32 (x2)(y2=?)
35 (x3)5.6291 (y3)

Substitute 30°C,32°Cand35°C for x1,x2,andx3 respectively, 4.2469kPa for y1 and 5.6291kPa for y3 in Equation (VI).

y2=(32°C30°C)(5.6291kPa4.2469kPa)(35°C30°C)+4.2469kPa=4.76kPa=Psat@32°C

Thus, the saturation pressure at temperature of 32°C is,

Psat@32°C=4.76kPa

Substitute 0.7 for ϕ1 and 4.76kPa for Psat@32°C in Equation (I).

Tdp=Tsat@(0.7×4.76kPa)=Tsat@3.33kPa (VII)

Here, saturation temperature at pressure of 3.33kPa is Tsat@3.33kPa.

Refer Table A-5 , “saturated water-pressure table”, and write saturation temperature at pressure of 3.33kPa using an interpolation method.

Show the saturation temperature corresponding to pressure as in Table (2).

Pressure

P(kPa)

Saturation temperature

Tsat(°C)

3 (x1)24.08 (y1)
3.33 (x2)(y2=?)
4 (x3)28.96 (y3)

Use excels and tabulates the values from Table (2) in Equation (VI) to get,

Tsat@3.33kPa=25.8°C

Substitute 25.8°C for Tsat@3.33kPa in Equation (VII).

Tdp=25.8°C

Refer Figure A-31, “psychometric chart at 1 atm total pressure”, and write the properties corresponding to dry bulb temperature of 32°C, dew point temperature of 25.8°C and relative humidity of 70%.

h1=86.35kJ/kgdryairω1=0.02114kgH2O/kgdryairν1=0.8939m3/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 dew point temperature of 25.8°C.

h2=57.43kJ/kgdryairω2=0.0147kgH2O/kgdryairν2=0.8501m3/kgdryair

Here, final specific volume is ν2.

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

hw=hf@20°C=83.915kJ/kg

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

Perform unit conversion of diameter from cmtom.

D=40cm=40cm[m100cm]=0.4m

Substitute 120m/min for V1 and 0.4m for D in Equation (II).

ν˙1=(120m/min)[π(0.4m)24]=15.08m3/min

Substitute 15.08m3/min for ν˙1 and 0.8939m3/kgdryair for ν1 in Equation (III).

m˙a1=15.08m3/min0.8939m3/kgdryair=16.87kg/min

Substitute 16.87kg/min for m˙a1, 0.02114kgH2O/kgdryair for ω1 and 0.0147kgH2O/kgdryair for ω2 in Equation (IV).

m˙w=(16.87kg/min)(0.021140.0147)=0.1086kg/min

Substitute 16.87kg/min for m˙a1, 86.35kJ/kgdryair for h1, 57.43kJ/kgdryair for h2, 0.1086kg/min for m˙w and 83.915kJ/kg for hw in Equation (V).

Q˙out=[(16.87kg/min)[(86.3557.43)kJ/kgdryair](0.1086kg/min)(83.915kJ/kg)]=478.7kJ/min

Hence, the rate of heat transfer is 478.7kJ/min.

(b)

Expert Solution
Check Mark
To determine

The mass flow rate of the water.

Answer to Problem 79P

The mass flow rate of the water is 19.09kg/min.

Explanation of Solution

Express the mass flow rate of the water.

m˙coolingwater=Q˙wcpΔT (VIII)

Here, mass flow rate of the water is Q˙w, specific heat at constant pressure of water is cp and rise in temperature is ΔT.

Conclusion:

Refer Table A-2, “ideal-gas specific heats of various common gases”, and write specific heat at constant pressure of water.

cp=4.18kJ/kg°C

Substitute 478.7kJ/min for Q˙w, 4.18kJ/kg°C for cp and 6°C for ΔT in Equation (VIII).

m˙coolingwater=478.7kJ/min(4.18kJ/kg°C)(6°C)=19.09kg/min

Hence, the mass flow rate of the water is 19.09kg/min.

c)

Expert Solution
Check Mark
To determine

The exit velocity of the airstream.

Answer to Problem 79P

The exit velocity of the airstream is 114m/min.

Explanation of Solution

Express the exit velocity of the airstream.

V2=ν2ν1V1 (IX)

Conclusion:

Substitute 0.8939m3/kgdryair for ν1, 0.8501m3/kgdryair for ν2 and 120m/min for V1 in Equation (IX).

V2=0.8501m3/kgdryair0.8939m3/kgdryair(120m/min)=114m/min

Hence, the exit velocity of the airstream is 114m/min.

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Chapter 14 Solutions

Thermodynamics: An Engineering Approach

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