THERMODYNAMICS: ENG APPROACH LOOSELEAF
THERMODYNAMICS: ENG APPROACH LOOSELEAF
9th Edition
ISBN: 9781266084584
Author: CENGEL
Publisher: MCG
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Chapter 11.10, Problem 42P

Refrigerant-134a enters the condenser of a residential heat pump at 800 kPa and 50°C at a rate of 0.022 kg/s and leaves at 750 kPa subcooled by 3°C. The refrigerant enters the compressor at 200 kPa superheated by 4°C. Determine (a) the isentropic efficiency of the compressor, (b) the rate of heat supplied to the heated room, and (c) the COP of the heat pump. Also, determine (d) the COP and the rate of heat supplied to the heated room if this heat pump operated on the ideal vapor-compression cycle between the pressure limits of 200 and 800 kPa.

FIGURE P11–42

Chapter 11.10, Problem 42P, Refrigerant-134a enters the condenser of a residential heat pump at 800 kPa and 50C at a rate of

(a)

Expert Solution
Check Mark
To determine

The isentropic efficiency of the compressor.

Answer to Problem 42P

The isentropic efficiency of the compressor is 0.757.

Explanation of Solution

Show the T-s diagram for process as in Figure (1).

THERMODYNAMICS: ENG APPROACH LOOSELEAF, Chapter 11.10, Problem 42P , additional homework tip  1

From Figure (1), write the specific enthalpy at state 3 is equal to state 4 due to throttling process.

h3h4

Here, specific enthalpy at state 3 and 4 is h3andh4 respectively.

Express isentropic efficiency of the compressor.

ηC=h2sh1h2h1 (I)

Here, specific enthalpy at state 1, 2 and 2s is h1,h2andh2s respectively.

Express the temperature at state 3.

T3=Tsat@750kPaTsub-cooled (II)

Here, saturated temperature at pressure of 750kPa is Tsat@750kPa and sub-cooled temperature is Tsub-cooled.

Express the temperature at state 1.

T1=Tsat@200kPaTsuperheated (III)

Here, saturated temperature at pressure of 200kPa is Tsat@750kPa and superheated temperature is Tsuperheated.

Express quality at state 2s.

s2=sf@800kPa+x2ssfg@800kPa (IV)

Here, specific entropy at saturated liquid and evaporation and 10°C is sf@800kPa and sfg@800kPa respectively.

Express specific enthalpy at state 2s.

h2s=hf@800kPa+x2shfg@800kPa (V)

Here, specific enthalpy at saturated liquid and evaporation and 10°C is hf@800kPa and hfg@800kPa respectively.

Conclusion:

Perform unit conversion of pressure at state 2 from kPatoMPa.

P2=800kPa[MPa1000kPa]=0.8MPa

Refer Table A-13, “superheated refrigerant 134a”, and write the specific enthalpy at state 2 corresponding to pressure at state 2 of 0.8MPa and temperature at state 2 of 50°C.

h2=286.71kJ/kg

Refer Table A-12, “saturated refrigerant-134a-pressure table” and write saturated temperature at pressure of 750kPa.

Tsat@750kPa=29.06°C

Substitute 29.06°C for Tsat@750kPa and 3°C for Tsub-cooled in Equation (II).

T3=29.06°C3°C=26.06°C

Refer Table A-12, “saturated refrigerant-134a-pressure table” and write specific enthalpy at state 3 corresponding to pressure at state 3 of 750kPa and temperature at state 3 of 26.06°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 at state 3 and specific enthalpy at state 3 respectively.

Show the specific enthalpy at state 3 corresponding to temperature as in Table (1).

Temperature at state 3

T3(°C)

Specific enthalpy at state 3

h3(kJ/kg)

26.69 (x1)88.82 (y1)
26.06 (x2)(y2=?)
29.06 (x3)92.22 (y3)

Substitute 26.69°C,26.06°Cand29.06°C for x1,x2andx3 respectively, 88.82kJ/kg for y1 and 92.22kJ/kg for y3 in Equation (VI).

y2=[(26.06°C26.69°C)kJ/kgK][(92.2288.82)kJ/kg](29.06°C26.69°C)+88.82kJ/kg=87.93kJ/kg=h3

Since the specific enthalpy at state 3 is equal to state 4 due to throttling process.

h3h4=87.93kJ/kg

Refer Table A-12, “saturated refrigerant-134a-pressure table” and write saturated temperature at pressure of 200kPa.

Tsat@200kPa=10.09°C

Substitute 10.09°C for Tsat@200kPa and 4°C for Tsuperheated in Equation (III).

T1=10.09°C+4°C=6.09°C

Refer Table A-12, “saturated refrigerant-134a-pressure table” and write specific enthalpy and entropy at state 1 corresponding to pressure at state 1 of 200kPa and temperature at state 1 of 6.09°C using an interpolation method.

h1=247.88kJ/kgs1=0.9507kJ/kgK

Here, specific entropy at state 1 is s1.

The specific entropy at state 1 is equal to specific entropy at state 1.

s1=s2=0.9507kJ/kgK

Here, specific entropy at state 2 is s2.

Refer Table A-12, “saturated refrigerant-134a-pressure table” and write the properties corresponding to pressure at state 2 of 800kPa

sf@800kPa=0.35408kJ/kgKsfg@800kPa=0.56445kJ/kgKhf@800kPa=95.48kJ/kghfg@800kPa=171.86kJ/kg

Substitute 0.9507kJ/kgK for s2, 0.35408kJ/kgK for sf@800kPa and 0.56445kJ/kgK for sfg@800kPa in Equation (IV).

0.9507kJ/kgK=0.35408kJ/kgK+x2s(0.56445kJ/kgK)x2s=1.056

Substitute 1.056 for x2s, 95.48kJ/kg for hf@800kPa and 171.86kJ/kg for hfg@800kPa in Equation (V).

h2s=95.48kJ/kg+(1.056)(171.86kJ/kg)=277.28kJ/kg

Substitute 277.28kJ/kgand247.88kJ/kg for h2sandh1 respectively, and 286.71kJ/kg for h2 in Equation (I).

ηC=277.28kJ/kg247.88kJ/kg286.71kJ/kg247.88kJ/kg=0.757

Hence, the isentropic efficiency of the compressor is 0.757.

(b)

Expert Solution
Check Mark
To determine

The rate of heat supplied to the heated room.

Answer to Problem 42P

The rate of heat supplied to the heated room is 4.373kW.

Explanation of Solution

Express the rate of heat supplied to the heated room.

Q˙H=m˙(h2h3) (VII)

Here, mass flow rate is m˙.

Conclusion:

Substitute 0.022kg/s for m˙, 286.71kJ/kgand87.93kJ/kg for h2andh3 respectively in equation (VII).

Q˙H=(0.022kg/s)(286.7187.93)kJ/kg=4.373kJ/s[kWkJ/s]=4.373kW

Hence, the rate of heat supplied to the heated room is 4.373kW.

(c)

Expert Solution
Check Mark
To determine

The COP of the heat pump.

Answer to Problem 42P

The COP of the heat pump is 5.12.

Explanation of Solution

Express the rate of work input.

W˙in=m˙(h2h1) (VIII)

Express coefficient of performance of heat pump.

COP=Q˙HW˙in (IX)

Conclusion:

Substitute 0.022kg/s for m˙, 286.71kJ/kgand247.88kJ/kg for h2andh1 respectively in equation (VIII).

W˙in=(0.022kg/s)(286.71247.88)kJ/kg=0.8542kJ/s[kWkJ/s]=0.8542kW

Substitute 0.8542kW for W˙in and 4.373kW for W˙in in Equation (IX).

COP=4.373kW0.8542kW=5.12

Hence, the COP of the heat pump is 5.12.

(d)

Expert Solution
Check Mark
To determine

The COP and the rate of heat supplied to the heated room.

Answer to Problem 42P

The COP and the rate of heat supplied to the heated room is 6.18and3.91kW respectively.

Explanation of Solution

Show the T-s diagram for ideal vapor compression cycle as in Figure (2).

THERMODYNAMICS: ENG APPROACH LOOSELEAF, Chapter 11.10, Problem 42P , additional homework tip  2

From Figure (2), write the specific enthalpy at state 3 is equal to state 4 due to throttling process.

h3h4

Express the coefficient of performance.

COP=h2h3h2h1 (X)

Express the rate of heat supplied to the heated room.

Q˙H=m˙(h2h3) (XI)

Conclusion:

Refer Table A-12, “saturated refrigerant-134a-pressure table”, and write the properties corresponding to initial pressure of 200kPa.

h1=hg=244.50kJ/kgs1=sg=0.9379kJ/kgK

Here, specific entropy at state 1 is s1, specific enthalpy and entropy at saturated vapor is hgandsg respectively.

Refer Table A-13, “superheated refrigerant 134a”, and write the specific enthalpy at state 2 corresponding to pressure at state 2 of 0.8MPa and specific entropy at state 2 (s2=s1) of 0.9379kJ/kgK using interpolation method.

Show the specific enthalpy at state 2 corresponding to specific entropy as in Table (2).

Specific entropy at state 2

s2(kJ/kgK)

Specific enthalpy at state 2

h2(kJ/kg)

0.9185 (x1)267.34 (y1)
0.9379 (x2)(y2=?)
0.9481 (x3)276.46 (y3)

Use Excels and substitute the values from Table (2) in Equation (VI) to get,

h2=95.48kJ/kg

Refer Table A-12, “saturated refrigerant-134a-pressure table”, and write the specific enthalpy at state 3 corresponding to pressure at state 3 (P3) of 800kPa.

h3=h4=hf=95.48kJ/kg

Here, specific enthalpy at saturated liquid is hf.

Since the specific enthalpy at state 3 is equal to state 4 due to throttling process.

h3h4=95.48kJ/kg

Substitute 273.29kJ/kgand95.48kJ/kg for h2andh3 respectively, and 244.50kJ/kg for h1 in Equation (X).

COP=273.29kJ/kg95.48kJ/kg273.29kJ/kg244.50kJ/kg=6.18

Substitute 0.022kg/s for m˙, 273.29kJ/kgand95.48kJ/kg for h2andh3 respectively in equation (XI).

Q˙H=(0.022kg/s)(273.2995.48)kJ/kg=3.91kJ/s[kWkJ/s]=3.91kW

Hence, the COP and the rate of heat supplied to the heated room is 6.18and3.91kW respectively.

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Chapter 11 Solutions

THERMODYNAMICS: ENG APPROACH LOOSELEAF

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