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Transcript of K10881 (chinmay sharma)rac
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R.A.C. Assignment Topic: V.C. Cycle
Submitted To, Submitted By,Mr. Aditya Mishra Sir Chinmay Sharma(K10881)
B.tech (Mechanical)sem./year:- 6th/ 3rd
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COP of Vapour Compression CycleDefinition of Refrigeration:
Refrigeration is the process of Producing lower temperature as compared to surrounding. To maintain lower temperature continuously, heat must be extracted continuously. Hence
Refrigeration system must operate in a cycle.
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Vapour compression Refrigeration System:There are four component in Vapour compression cycle. 1. Compressor:- Compresses the refrigerant to high pressure and temperature from low
pressure and temperature.
2. Condenser:- The latent heat of refrigerant is removed by circulating water or atmospheric air.
3. Expansion Valve:- In the throttle valve where the pressure is reduced at a controlled rate.
4. Evaporator:- A liquid-Vapour mixture refrigerant then enters the evaporator at low pressure where the latent heat of evaporation is converted into vapour and the cycle repeats.
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Fig:- The P-h diagram is another convenient diagram often used to illustrate the refrigeration
cycle.
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Determination of COP:
Assumptions made for drawing T-S and P-h Diagram:1. The refrigerant leaving the evaporator is dry and saturated.2. The compression of vapour in the evaporator is isentropic.3. There is no sub cooling of the refrigerant in the condenser.4. There is no pressure losses in the system.
Conditions of vapour at the end of compression:There are three different conditions at which the refrigerant from the compressor.a. Vapour is dry and saturated.b. Vapour is wet condition.c. Vapour is superheated condition.
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COP Of V.C. CycleApply Steady flow energy equation ( Neglect K.E & P.E changes)1. Compressor: Q1-2 + C1
2/2 + Z 1 + h1 = W1-2 + C22/2 + Z 2+ h2
W1-2 = - ( h2 – h1)2. Condenser:Q2-3 + C2
2/2 + Z 2 + h2 = W2-3 + C32/2 + Z 3+ h3
Q2-3 = - (h2 - h3)3. Throttle Valve:Q3-4 + C3
2/2 + Z 3 + h3 = W3-4 + C42/2 + Z 4+ h4
h3 = h4 (Isenthalpic process)
4. Evaporator:Q4-1 + C4
2/2 + Z 4 + h4 = W4-1 + C12/2 + Z 1+ h1
Q4-1 + h4 = h1
Q4-1 = h1 – h4
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Co-efficient of Performance: It is the ratio of net refrigerating effect to the work required to produce that effect.
Co-efficient of performance = Refrigerating effect/ Work input = ( h1 – h4 ) / (h2 – h1)
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Effects of variation of properties on the performance of Vapour compression cycle:
Case 1:- Decrease in Evaporator:
RE= h1-h4
Win=h2-h1
COP= RE/Win
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• Effects:-Reduction in Refrigeration effectsIncrease in work inputDecrease in COPDecrease in volumetric efficiency due to increase in pressure
ratio.
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RE= h1-h4
Win=h2-h1
COP= RE/Win
• Case 2:- Increase in condenser pressure
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• Effects:-Reduction in Refrigeration effectsIncrease in work inputDecrease in COPDecrease in volumetric efficiency due to increase in pressure
ratio.
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RE= h1-h4
Win=COP= RE/Win
• Case 3:- Superheating
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• Effects:-Increase in Refrigeration effectIncrease in work input due to temperature at the inlet to
compressor increase.COP may increase or decrease depending on the refrigerant. In
case of R- 12 superheating result in increase in COP where as in case of NH3 superheating results in decrease in COP.
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