THERMODYNAMICS LLF W/ CONNECT ACCESS
THERMODYNAMICS LLF W/ CONNECT ACCESS
9th Edition
ISBN: 9781264446889
Author: CENGEL
Publisher: MCG
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Chapter 11.10, Problem 115RP

An air conditioner with refrigerant-134a as the working fluid is used to keep a room at 26°C by rejecting the waste heat to the outside air at 34°C. The room is gaining heat through the walls and the windows at a rate of 250 kJ/min while the heat generated by the computer, TV, and lights amounts to 900 W. An unknown amount of heat is also generated by the people in the room. The condenser and evaporator pressures are 1200 and 500 kPa, respectively. The refrigerant is saturated liquid at the condenser exit and saturated vapor at the compressor inlet. If the refrigerant enters the compressor at a rate of 100 L/min and the isentropic efficiency of the compressor is 75 percent, determine (a) the temperature of the refrigerant at the compressor exit, (b) the rate of heat generation by the people in the room, (c) the COP of the air conditioner, and (d) the minimum volume flow rate of the refrigerant at the compressor inlet for the same compressor inlet and exit conditions.

FIGURE P11–115

Chapter 11.10, Problem 115RP, An air conditioner with refrigerant-134a as the working fluid is used to keep a room at 26C by

(a)

Expert Solution
Check Mark
To determine

The temperature of the refrigerant at the compressor exit.

Answer to Problem 115RP

The temperature of the refrigerant at the compressor exit is 54.5°C.

Explanation of Solution

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

THERMODYNAMICS LLF W/ CONNECT ACCESS, Chapter 11.10, Problem 115RP

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

h3h4 (I)

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

Express the specific enthalpy at state 2.

ηC=h2sh1h2h1 (II)

Here, specific enthalpy at state 2s is h2s, isentropic efficiency is ηC and specific enthalpy at state 1 and 2 is h1andh2 respectively.

Conclusion:

Perform the unit conversion of pressure at state 1 from kPatoMPa.

P1=500kPa=500kPa[MPa1000kPa]=0.5MPa

Refer Table A-13, “superheated refrigerant-134a”, and write the properties corresponding to pressure of 0.5MPa.

h1=259.36kJ/kgv1=0.04117m3/kgs1=0.9242kJ/kgK

Here, specific enthalpy, volume and entropy is h1,v1ands1 respectively.

Perform the unit conversion of pressure at state 2 from kPatoMPa.

P2=1200kPa=1200kPa[MPa1000kPa]=1.2MPa

Refer Table A-12, “saturated refrigerant-134a-pressure table”, and write the specific enthalpy at state 3 corresponding to pressure at state 3 of 1200kPa.

h3=hf=117.79kJ/kg

Here, specific enthalpy at saturated liquid is hf.

Substitute 117.79kJ/kg for h3 in Equation (I).

h4=117.79kJ/kg

Refer Table A-13, “superheated refrigerant 134a”, and write the specific enthalpy at state 2s corresponding to pressure at state 2 of 1.2MPa and specific entropy at state 2 (s2=s1) of 0.9242kJ/kgK using interpolation method.

Write the formula of interpolation method of two variables.

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

Here, the variables denote by x and y is specific entropy at state 2 and specific enthalpy at state 2 respectively.

Show the specific enthalpy at state 2s corresponding to specific entropy as in Table (1).

Specific entropy at state 2

s2(kJ/kgK)

Specific enthalpy at state 2s

h2(kJ/kg)

0.9132 (x1)273.92 (y1)
0.9242 (x2)(y2=?)
0.9268 (x3)278.28 (y3)

Substitute 0.9132kJ/kgK,0.9242kJ/kgKand0.9268kJ/kgK for x1,x2andx3 respectively, 273.92kJ/kg for y1 and 278.28kJ/kg for y3 in Equation (III).

y2=[(0.92420.9132)kJ/kgK][(278.28273.92)kJ/kg](0.92680.9132)kJ/kgK+273.92kJ/kg=277.45kJ/kg=h2s

Thus, the specific enthalpy at state 2s is,

h2s=277.45kJ/kg

Substitute 0.75 for ηC, 277.45kJ/kg for h2s and 259.36kJ/kg for h1 in Equation (II).

0.75=277.45kJ/kg259.36kJ/kgh2259.36kJ/kgh2=283.48kJ/kg

Refer Table A-13, “superheated refrigerant 134a”, and write the temperature at state 2 corresponding to pressure at state 2 of 1.2MPa and specific enthalpy at state 2 of 283.48kJ/kg using interpolation method.

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

Specific enthalpy at state 2s

h2(kJ/kg)

Temperature at state 2

T2(°C)

278.28 (x1)50 (y1)
283.48 (x2)(y2=?)
289.66 (x3)60 (y3)

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

T2=54.5°C

Hence, the temperature of the refrigerant at the compressor exit is 54.5°C.

(b)

Expert Solution
Check Mark
To determine

The rate of heat generation by the people in the room.

Answer to Problem 115RP

The rate of heat generation by the people in the room is 0.665kW.

Explanation of Solution

Express the mass flow rate of the refrigerant.

m˙=ν˙1v1 (IV)

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

Express the refrigeration load.

Q˙L=m˙(h1h4) (V)

Express the rate of heat generation by the people in the room.

Q˙people=Q˙LQ˙heatQ˙equip (VI)

Here, rate of heat generated is Q˙heat and rate of heat generated by equipment is Q˙equip.

Conclusion:

Substitute 100L/min for ν˙1 and 0.04117m3/kg for v1 in Equation (IV).

m˙=100L/min0.04117m3/kg=100L/min[m31000L][min60s]0.04117m3/kg=0.04048kg/s

Substitute 0.04048kg/s for m˙, 117.79kJ/kg for h4 and 259.36kJ/kg for h1 in Equation (V).

Q˙L=0.04048kg/s(259.36kJ/kg117.79kJ/kg)=5.731kJ/s[kWkJ/s]=5.731kW

Substitute 5.731kW for Q˙L, 250kJ/min for Q˙heat and 900W for Q˙equip in Equation (VI).

Q˙people=5.731kW250kJ/min900W=5.731kW[(250kJ/min)min60s][(900W)kW1000W]=5.731kW(4.167kJ/s)[kWkJ/s]0.9kW

=5.731kW4.167kW0.9kWQ˙people=0.665kW

Hence, the rate of heat generation by the people in the room is 0.665kW.

(c)

Expert Solution
Check Mark
To determine

The COP of the air conditioner.

Answer to Problem 115RP

The COP of the air conditioner is 5.87.

Explanation of Solution

Express the rate of work input.

W˙in=m˙(h2h1) (VII)

Express the coefficient of performance of the air conditioner.

COP=Q˙LW˙in (VIII)

Conclusion:

Substitute 0.04048kg/s for m˙, 283.48kJ/kg for h2 and 259.36kJ/kg for h1 in Equation (VII).

W˙in=0.04048kg/s(283.48kJ/kg259.36kJ/kg)=0.9764kJ/s[kWkJ/s]=0.9764kW

Substitute 0.9764kW for W˙in and 5.731kW for Q˙L in Equation (VIII).

COP=5.731kW0.9764kW=5.87

Hence, the COP of the air conditioner is 5.87.

(d)

Expert Solution
Check Mark
To determine

The minimum volume flow rate of the refrigerant at the compressor inlet.

Answer to Problem 115RP

The minimum volume flow rate of the refrigerant at the compressor inlet is 15.7L/min.

Explanation of Solution

Express the reversible coefficient of performance of the cycle.

COPrev=1THTL1 (IX)

Here, high and low temperature medium is THandTL respectively.

Express corresponding minimum power input.

W˙in,min=Q˙LCOPrev (X)

Express the minimum mass flow rate.

m˙min=W˙in,minh2h1 (XI)

Express the minimum volume flow rate of the refrigerant at the compressor inlet

ν˙1,min=m˙minv1 (XII)

Conclusion:

Substitute 34°C for TH and 26°C for TL in Equation (IX).

COPrev=134°C26°C1=1(34+273)K(26+273)K1=1307K299K1=37.38

Substitute 5.731kW for Q˙L and 37.38 for COPrev in Equation (X).

W˙in,min=5.731kW37.38=0.1533kW

Substitute 0.1533kW for W˙in,min, 283.48kJ/kg for h2 and 259.36kJ/kg for h1 in Equation (XI).

m˙min=0.1533kW283.48kJ/kg259.36kJ/kg=0.1533kW[kJ/skW]283.48kJ/kg259.36kJ/kg=0.1533kJ/s283.48kJ/kg259.36kJ/kg=0.006358kg/s

Substitute 0.006358kg/s for m˙min and 0.04117m3/kg for v1 in Equation (XII).

ν˙1,min=(0.006358kg/s)(0.04117m3/kg)=0.0002618m3/s[1000Lm3][60mins]=15.7L/min

Hence, the minimum volume flow rate of the refrigerant at the compressor inlet is 15.7L/min.

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Chapter 11 Solutions

THERMODYNAMICS LLF W/ CONNECT ACCESS

Ch. 11.10 - The COP of vapor-compression refrigeration cycles...Ch. 11.10 - A 10-kW cooling load is to be served by operating...Ch. 11.10 - An ice-making machine operates on the ideal...Ch. 11.10 - An air conditioner using refrigerant-134a as the...Ch. 11.10 - An ideal vapor-compression refrigeration cycle...Ch. 11.10 - A refrigerator operates on the ideal...Ch. 11.10 - A refrigerator uses refrigerant-134a as the...Ch. 11.10 - An ideal vapor-compression refrigeration cycle...Ch. 11.10 - A refrigerator uses refrigerant-134a as its...Ch. 11.10 - A refrigerator uses refrigerant-134a as the...Ch. 11.10 - A commercial refrigerator with refrigerant-134a as...Ch. 11.10 - The manufacturer of an air conditioner claims a...Ch. 11.10 - Prob. 24PCh. 11.10 - How is the second-law efficiency of a refrigerator...Ch. 11.10 - Prob. 26PCh. 11.10 - Prob. 27PCh. 11.10 - Prob. 28PCh. 11.10 - Bananas are to be cooled from 28C to 12C at a rate...Ch. 11.10 - A vapor-compression refrigeration system absorbs...Ch. 11.10 - A room is kept at 5C by a vapor-compression...Ch. 11.10 - Prob. 32PCh. 11.10 - A refrigerator operating on the vapor-compression...Ch. 11.10 - When selecting a refrigerant for a certain...Ch. 11.10 - A refrigerant-134a refrigerator is to maintain the...Ch. 11.10 - Consider a refrigeration system using...Ch. 11.10 - A refrigerator that operates on the ideal...Ch. 11.10 - A heat pump that operates on the ideal...Ch. 11.10 - Do you think a heat pump system will be more...Ch. 11.10 - What is a water-source heat pump? 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What is the effect on the...Ch. 11.10 - Prob. 50PCh. 11.10 - How does the COP of a cascade refrigeration system...Ch. 11.10 - Consider a two-stage cascade refrigeration cycle...Ch. 11.10 - Can a vapor-compression refrigeration system with...Ch. 11.10 - Prob. 54PCh. 11.10 - A certain application requires maintaining the...Ch. 11.10 - Prob. 56PCh. 11.10 - Repeat Prob. 1156 for a flash chamber pressure of...Ch. 11.10 - Prob. 59PCh. 11.10 - A two-stage compression refrigeration system with...Ch. 11.10 - A two-stage compression refrigeration system with...Ch. 11.10 - A two-evaporator compression refrigeration system...Ch. 11.10 - A two-evaporator compression refrigeration system...Ch. 11.10 - Repeat Prob. 1163E if the 30 psia evaporator is to...Ch. 11.10 - Consider a two-stage cascade refrigeration cycle...Ch. 11.10 - How does the ideal gas refrigeration cycle differ...Ch. 11.10 - Prob. 67PCh. 11.10 - Devise a refrigeration cycle that works on the...Ch. 11.10 - How is the ideal gas refrigeration cycle modified...Ch. 11.10 - Prob. 70PCh. 11.10 - How do we achieve very low temperatures with gas...Ch. 11.10 - An ideal gas refrigeration system operates with...Ch. 11.10 - Air enters the compressor of an ideal gas...Ch. 11.10 - Repeat Prob. 1173 for a compressor isentropic...Ch. 11.10 - An ideal gas refrigeration cycle uses air as the...Ch. 11.10 - Rework Prob. 1176E when the compressor isentropic...Ch. 11.10 - A gas refrigeration cycle with a pressure ratio of...Ch. 11.10 - A gas refrigeration system using air as the...Ch. 11.10 - An ideal gas refrigeration system with two stages...Ch. 11.10 - Prob. 81PCh. 11.10 - Prob. 82PCh. 11.10 - What are the advantages and disadvantages of...Ch. 11.10 - Prob. 84PCh. 11.10 - Prob. 85PCh. 11.10 - Prob. 86PCh. 11.10 - Prob. 87PCh. 11.10 - Heat is supplied to an absorption refrigeration...Ch. 11.10 - An absorption refrigeration system that receives...Ch. 11.10 - An absorption refrigeration system receives heat...Ch. 11.10 - Heat is supplied to an absorption refrigeration...Ch. 11.10 - Prob. 92PCh. 11.10 - Prob. 93PCh. 11.10 - Consider a circular copper wire formed by...Ch. 11.10 - An iron wire and a constantan wire are formed into...Ch. 11.10 - Prob. 96PCh. 11.10 - Prob. 97PCh. 11.10 - Prob. 98PCh. 11.10 - Prob. 99PCh. 11.10 - Prob. 100PCh. 11.10 - Prob. 101PCh. 11.10 - Prob. 102PCh. 11.10 - A thermoelectric cooler has a COP of 0.18, and the...Ch. 11.10 - Prob. 104PCh. 11.10 - Prob. 105PCh. 11.10 - Prob. 106PCh. 11.10 - Rooms with floor areas of up to 15 m2 are cooled...Ch. 11.10 - Consider a steady-flow Carnot refrigeration cycle...Ch. 11.10 - Consider an ice-producing plant that operates on...Ch. 11.10 - A heat pump that operates on the ideal...Ch. 11.10 - A heat pump operates on the ideal...Ch. 11.10 - A large refrigeration plant is to be maintained at...Ch. 11.10 - Repeat Prob. 11112 assuming the compressor has an...Ch. 11.10 - An air conditioner with refrigerant-134a as the...Ch. 11.10 - A refrigerator using refrigerant-134a as the...Ch. 11.10 - Prob. 117RPCh. 11.10 - An air conditioner operates on the...Ch. 11.10 - Consider a two-stage compression refrigeration...Ch. 11.10 - A two-evaporator compression refrigeration system...Ch. 11.10 - The refrigeration system of Fig. P11122 is another...Ch. 11.10 - Repeat Prob. 11122 if the heat exchanger provides...Ch. 11.10 - An aircraft on the ground is to be cooled by a gas...Ch. 11.10 - Consider a regenerative gas refrigeration cycle...Ch. 11.10 - An ideal gas refrigeration system with three...Ch. 11.10 - Prob. 130RPCh. 11.10 - Derive a relation for the COP of the two-stage...Ch. 11.10 - Prob. 133FEPCh. 11.10 - Prob. 134FEPCh. 11.10 - Prob. 135FEPCh. 11.10 - Prob. 136FEPCh. 11.10 - Prob. 137FEPCh. 11.10 - An ideal vapor-compression refrigeration cycle...Ch. 11.10 - Prob. 139FEPCh. 11.10 - An ideal gas refrigeration cycle using air as the...Ch. 11.10 - Prob. 141FEPCh. 11.10 - Prob. 142FEP
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