THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<
THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<
9th Edition
ISBN: 9781266657610
Author: CENGEL
Publisher: MCG CUSTOM
bartleby

Videos

Textbook Question
Book Icon
Chapter 11.10, Problem 33P

A refrigerator operating on the vapor-compression refrigeration cycle using refrigerant-134a as the refrigerant is considered. The temperatures of the cooled space and the ambient air are at 10°F and 80°F, respectively. R-134a enters the compressor at 20 psia as a saturated vapor and leaves at 140 psia and 160°F. The refrigerant leaves the condenser as a saturated liquid. The rate of cooling provided by the system is 45,000 Btu/h. Determine (a) the mass flow rate of R-134a and the COP, (b) the exergy destruction in each component of the cycle and the second-law efficiency of the compressor, and (c) the second-law efficiency of the cycle and the total exergy destruction in the cycle.

(a)

Expert Solution
Check Mark
To determine

The mass flow rate of R-134a and the COP.

Answer to Problem 33P

The mass flow rate of R-134a and the COP is 0.2177lbm/s and 2.006 respectively.

Explanation of Solution

Show the T-s diagram for vapor-compression refrigeration cycle as in Figure (1).

THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<, Chapter 11.10, Problem 33P

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 the work input.

win=h2h1 (I)

Here, specific enthalpy at state 2 and 1 is h2andh1 respectively.

Express heat supplied to the cooled space.

qH=h2h3 (II)

Express the heat removed from the cooled space.

qL=qHwin (III)

Express quality at state 4.

h4=hf@20psia+x4hfg@20psia (IV)

Here, specific enthalpy at saturated liquid and evaporation and 20psia is hf@20psia and hfg@20psia respectively.

Express specific entropy at state 4.

s4=sf@20psia+x4sfg@20psia (V)

Here, specific entropy at saturated liquid and evaporation and 20psia is sf@20psia and sfg@20psia respectively.

Express mass flow rate of R-134a.

m˙=Q˙LqL (VI)

Here, rate of heat lost is Q˙L.

Express the COP of the cycle.

COP=qLwin (VII)

Conclusion:

Refer Table A-12E, “saturated refrigerant-134a-pressure table”, and write the properties corresponding to initial pressure (P1) of 20psia.

h1=hg=102.71Btu/lbms1=sg=0.2257Btu/lbmR

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

Refer Table A-13E, “superheated refrigerant-134a”, and write the properties corresponding to pressure at state 2(P2) of 140psia and final temperature (T2) of 160°F.

h2=131.37Btu/lbms2=0.2444Btu/lbmR

Here, specific entropy at state 2 is s2.

Refer Table A-12E, “saturated refrigerant-134a-pressure table”, and write the properties corresponding to pressure at state 3(P3) of 140psia.

h3=hf=45.31Btu/lbms3=sf=0.09215Btu/lbmR

Here, specific entropy at state 3 is s3, specific enthalpy and entropy at saturated liquid is hfandsf respectively.

As specific enthalpy at state 3 is equal to specific enthalpy at state 4,

h3h4=45.31Btu/lbm

Refer Table A-12E, “saturated refrigerant-134a-pressure table”, and write the properties corresponding to pressure at state 4(P4) of 20psia.

hf@20psia=11.436Btu/lbmhfg@20psia=91.302Btu/lbmsf@20psia=0.0260Btu/lbmRsfg@20psia=0.1996Btu/lbmR

Substitute 45.31Btu/lbm for h4, 11.436Btu/lbm for hf@20psia and 91.302Btu/lbm for hfg@20psia in Equation (IV).

45.31Btu/lbm=11.436Btu/lbm+(x4)91.302Btu/lbmx4=0.3710

Substitute 0.0260Btu/lbmRand0.1996Btu/lbmR for sf@20psia and sfg@20psia respectively and 0.3710 for x4 in Equation (V).

s4=(0.0260Btu/lbmR)+(0.3710)(0.1996Btu/lbmR)=0.1001Btu/lbmR

Substitute 131.37Btu/lbm for h2 and 102.74Btu/lbm for h1 in Equation (I).

win=131.37Btu/lbm102.74Btu/lbm=28.63Btu/lbm

Substitute 131.37Btu/lbm for h2 and 45.31Btu/lbm for h3 in Equation (II).

qH=131.37Btu/lbm45.31Btu/lbm=86.06Btu/lbm

Substitute 86.06Btu/lbm for qH and 28.63Btu/lbm for win in Equation (III).

qL=86.06Btu/lbm28.63Btu/lbm=57.43Btu/lbm

Substitute 45000Btu/h for Q˙L and 57.43Btu/lbm for qL in Equation (VI).

m˙=45000Btu/h57.43Btu/lbm=(45000Btu/h)Btu/s3600Btu/h57.43Btu/lbm=12.5Btu/s57.43Btu/lbm=0.2177lbm/s

Substitute 57.43Btu/lbm for qL and 28.63Btu/lbm for win in Equation (VII).

COP=57.43Btu/lbm28.63Btu/lbm=2.006

Hence, the mass flow rate of R-134a and the COP is 0.2177lbm/s and 2.006 respectively.

(b)

Expert Solution
Check Mark
To determine

The exergy destruction in each component of the cycle and the second-law efficiency of the compressor.

Answer to Problem 33P

The exergy destruction in compressor is 2.203Btu/s, condenser is 0.8313Btu/s, expansion valve is 0.9358Btu/s, evaporator is 0.3996kJ/kg and second-law efficiency of the compressor is 64.7%.

Explanation of Solution

For compressor:

Express the exergy destruction in compressor.

Exdest,comp=m˙T0sgen,12=m˙T0(s2s1) (VIII)

Here, surrounding temperature is T0, entropy generation during process 1-2 is sgen,12.

For condenser:

Express the exergy destruction in condenser.

Exdest,cond=m˙T0sgen,23=m˙T0[(s3s2)+qHTH] (IX)

Here, entropy generation during process 2-3 is sgen,23 and high temperature medium is TH.

For expansion valve:

Exdest,expval=m˙T0sgen,34=m˙T0(s4s3) (X)

For evaporator:

Express the exergy destruction in evaporator.

Exdest,evap=m˙T0sgen,41=T0[(s1s4)qLTL] (XI)

Here, entropy generation during process 4-1 is sgen,41 and low temperature medium is TL.

Express the power input of the compressor.

W˙in=m˙win (XII)

Express second law efficiency of the compressor.

ηII=1Exdest,compW˙in×100% (XIII)

Conclusion:

Perform unit conversion of surrounding temperature from °FtoR.

T0=80°F=(80+460)R=540R

Perform unit conversion of high temperature medium from °FtoR.

TH=80°F=(80+460)R=540R

Perform unit conversion of low temperature medium from °FtoR.

TL=10°F=(10+460)R=470R

Substitute 0.2177lbm/s for m˙, 540R for T0 and 0.2444Btu/lbmR for s2 and 0.2257Btu/lbmR for s1 respectively in Equation (VIII).

Exdest,comp=(0.2177lbm/s)(540R)(0.24440.2257)Btu/lbmR=2.203Btu/s

Hence, the exergy destruction in compressor is 2.203Btu/s.

Substitute 0.2177lbm/s for m˙, 540R for T0, 86.06Btu/lbm for qH, 540R for TH, 0.09215Btu/lbmRand0.2444Btu/lbmR for s3ands2 respectively, in Equation (IX).

Exdest,cond=(0.2177lbm/s)(540R)[(0.092150.2444)Btu/lbmR+86.06Btu/lbm540R]=(0.2177lbm/s)(540R)(0.007073Btu/lbmR)=0.8313Btu/s

Hence, the exergy destruction in condenser is 0.8313Btu/s.

Substitute 0.1001Btu/lbmRand0.09215Btu/lbmR for s4ands3 respectively, 0.2177lbm/s for m˙, 540R for T0 in Equation (X).

Exdest,expval=(0.2177lbm/s)(540R)(0.10010.09215)Btu/lbmR=(0.2177lbm/s)(540R)(0.007961Btu/lbmR)=0.9358Btu/s

Hence, the exergy destruction in expansion valve is 0.9358Btu/s.

Substitute 0.2177lbm/s for m˙, 540R for T0, 57.43Btu/lbm for qL, 470R for TL, 0.2257Btu/lbmRand0.1001Btu/lbmR for s1ands4 respectively, in Equation (XI).

Exdest,evap=(0.2177lbm/s)(540R)[(0.22570.1001)Btu/lbmR+57.43Btu/lbm470R]=(0.2177lbm/s)(540R)(0.003400Btu/lbmR)=0.3996Btu/s

Hence, the exergy destruction in evaporator is 0.3996Btu/s.

Substitute 0.2177lbm/s for m˙ and 28.63Btu/lbm for win in Equation (XII).

W˙in=(0.2177lbm/s)(28.63Btu/lbm)=6.232Btu/s

Substitute 6.232Btu/s for W˙in and 2.203Btu/s for Exdest,comp in Equation (XIII).

ηII=12.203Btu/s6.232Btu/s×100%=0.6465×100%=64.65%64.7%

Hence, the second-law efficiency of the compressor is 64.7%.

(c)

Expert Solution
Check Mark
To determine

The second-law efficiency of the cycle and the total exergy destruction in the cycle.

Answer to Problem 33P

The second-law efficiency of the cycle is 29.9% and the total exergy destruction in the cycle is 4.370Btu/s.

Explanation of Solution

Express the exergy of the heat transferred from the low temperature medium.

E˙xQ˙L=Q˙L[1T0TL] (XIV)

Determine the second law efficiency of the cycle.

ηII=E˙xQ˙LW˙in×100% (XV)

Express the total exergy destruction in the cycle.

E˙xdest,total=W˙inE˙xQ˙L (XVI)

Conclusion:

Substitute 45000Btu/h for Q˙L, 540Rand470R for T0andTL respectively in Equation (XIV).

E˙xQ˙L=(45000Btu/h)[1540R470R]=[(45000Btu/h)Btu/s3600Btu/h](0.1489)=(12.5Btu/s)(0.1489)=1.862Btu/s

Substitute 1.862Btu/s for E˙xQ˙L and 6.232Btu/s for W˙in in Equation (XV).

ηII=1.862Btu/s1.862Btu/s×100%=29.9%

Hence, the second-law efficiency of the cycle is 29.9%.

Substitute 1.862Btu/s for E˙xQ˙L and 6.232Btu/s for W˙in in Equation (XVI).

E˙xdest,total=6.232Btu/s1.862Btu/s=4.370Btu/s

Hence, the total exergy destruction in the cycle is 4.370Btu/s.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!
Students have asked these similar questions
Refrigerant-134a enters the compressor of a cooling system as superheated vapor at 0.18 MPa and 0°C with a flow rate of 0.15 kg/s. It exits the compressor at 0.8 MPa and 60°C. Post compression, the refrigerant is cooled in the condenser to 28°C and 1.4 MPa. Subsequently, it's throttled to 0.16 MPa. Neglecting any heat transfer and pressure drops in the pipelines between the components, represent the cycle on a T-s diagram concerning saturation lines. Calculate: (a) The rate of heat extraction from the cooling area and the energy input to the compressor. (b) The isentropic efficiency of the compressor. (c) The Coefficient of Performance (COP) of the cooling system.
A refrigerator uses refrigerant-134a as its working fluid and operates on the ideal vapor-compression refrigeration cycle. The refrigerant evaporates at 5.00°F and condenses at 180 psia. This unit serves a 45000 Btu/h cooling load. Determine the mass flow rate of the refrigerant and the power that this unit will require. (Take the required values from saturated refrigerant-134a tables.) (Round the final answers to three decimal places.) The mass flow rate of the refrigerant is Ibm/h, and the power requirement is kW.
A heat pump uses R-134a as the refrigerant. The refrigerant enters the adiabatic compressor as saturated vapor at 120 kPa and exits it (the compressor) at 800 kPa and 50°C. The refrigerant exits the condenser as saturated liquid at 800 kPa. Then, the refrigerant flows through an adiabatic expansion valve, reducing the pressure back to the evaporator pressure of 120 kPa. The compressor power is 1.25 kW. a) Calculate the mass flow rate of the refrigerant (R-134a) in kg/s or g/s.                                                                    b) Calculate the heat power delivered from the condenser in kW.                                                                       c) Calculate the coefficient of performance (COP) of the heat pump, COP_HP.d) Calculate the refrigerant’s vapor quality entering the evaporator.

Chapter 11 Solutions

THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<

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? How does the COP...Ch. 11.10 - A heat pump operates on the ideal...Ch. 11.10 - Refrigerant-134a enters the condenser of a...Ch. 11.10 - A heat pump that operates on the ideal...Ch. 11.10 - The liquid leaving the condenser of a 100,000...Ch. 11.10 - Reconsider Prob. 1144E. What is the effect on the...Ch. 11.10 - A heat pump using refrigerant-134a heats a house...Ch. 11.10 - A heat pump using refrigerant-134a as a...Ch. 11.10 - Reconsider Prob. 1148. 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
Knowledge Booster
Background pattern image
Mechanical Engineering
Learn more about
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, mechanical-engineering and related others by exploring similar questions and additional content below.
Similar questions
SEE MORE QUESTIONS
Recommended textbooks for you
Text book image
Refrigeration and Air Conditioning Technology (Mi...
Mechanical Engineering
ISBN:9781305578296
Author:John Tomczyk, Eugene Silberstein, Bill Whitman, Bill Johnson
Publisher:Cengage Learning
The Refrigeration Cycle Explained - The Four Major Components; Author: HVAC Know It All;https://www.youtube.com/watch?v=zfciSvOZDUY;License: Standard YouTube License, CC-BY