refrigeration systems 2
TRANSCRIPT
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Principles of Vapour Compression Refrigeration
Learning Outcomes At the end of this lecture you should be able to1. Describe the p-h chart and be able to represent the
cycle on this2. Describe the terms refrigeration duty, heat of rejection,
refrigeration effect, work input and coefficient of performance
3. Determine the refrigeration effect and coefficient of performance, work input of a simple refrigeration cycle on a pressure – enthalpy chart
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The cycle recapped
Condenser Evaporator Cooled medium
Cooling medium
Expansion device
Compressor
High pressure Low pressure
1
4 3
2
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Compressors
• Pump • Compress
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Reciprocating compressor
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Scroll compressor
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Screw compressor
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Plate Heat exchanger Evaporators
•
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Shell and tube Evaporators
•
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Plate fin evaporator
•
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Plate Heat exchanger condensers
•
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Shell and tube condensers
•
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Air cooled condensers
•
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Evaporative Condensers
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Expansion Device
• To expand the fluid• To control superheat
at compressor inlet
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The (reversible) Cycle
pressure
Enthalpy
High pressure
Low pressure
Inlet to compressor
- superheated
Isentropic compression
CondensingSome subcooling
Isenthalpic
expansion
Evaporation
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Something for you
Condenser Evaporator
P=40oC P=5oCT=15oCT=85oC
Cooled medium
Cooling medium
T=A
T=F
T=B T=C
T=13 oC
D
E
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Something for you1. What pressure is the SUCTION pressure gauge reading?
……………………. bar2. What pressure is the DISCHARGE pressure gauge reading?
…………………. bar3. What is the degree of Suction SUPERHEAT?…………………. K4. What is the degree of Discharge SUPERHEAT?…………………. K5. What do you consider is a reasonable temperature for the condenser
cooling medium 'A'? 0, 10, 25, 40 oC6. What reading would you expect at thermometer 'B'? 42, 38, 21, 5 oC7. What reading would you expect at thermometer 'C'?-5, 5, 35, 13 oC 8. What would you see in sight glass 'D'?a. Gas only, b. Liquid and a few bubbles, c. Mainly bubbles (foam)d. Liquid only, 9. What would you see in sight glass 'E'?
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The 1st law of thermodynamics
• Energy is not destroyed or created• Conservation of energy
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The thermodynamic boundary
Condenser Evaporator Cooled medium
Cooling medium
Expansion device
Compressor
High pressure Low pressure
1
4 3
2
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The First Law of Thermodynamics
Pump
inout
m hout m hin
W
Q - W= m (hout – hin) + KE + PE
Q
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The 1st law of thermodynamics
• Q is +tive if heat is transferred to the system ie evaporator
• Q is -tive if heat is transferred from the system ie condenser
• W is +tive if work done by the system is ie turbine
• W is -tive if work done on the system is ie compressor
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Applying the first law to the Compressor
Compressor
12
m h2 m h1
W
Q= m (h2 – h1) +W
W is the power absorbed, or work input
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First Law to the Condenser
Condenser
3
2
m h2
m h3
Q
Q= m (h3 – h2) +W
Q is the total heat of rejection
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1st law to the expansion device
Expansion device
4 3 m h3
m h4
Q= m (h3 – h2) +W
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4
1
First Law to the Evaporator
Evaporator
m h1
m h4
Q
Q= m (h1 – h4) +W
Q is the refrigeration duty or cooling capacity
(h1 – h4) is the refrigeration effect
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COP – coefficient of performance
Q= cooling duty divided by power absorbed
COP is normally between 4 and 1
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A worked example A vapour compression cycle operating with R134a is
used to chill water from 12 to 6oC. The condenser rejects heat to ambient air at 27oC.
Choose realistic values for following cycle properties. Assume the compressor operates reversibly.
• Evaporating temperature• Evaporating pressure• The superheat at the compressor inlet • Condensing temperature • Condensing pressure• The subcooling at the condenser outlet.
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A worked example Plot the cycle on p-h chart and determine the enthalpy at the compressor inlet compressor outlet, evaporator inlet, condenser outletAssuming that the refrigerant is flowing at 5kg/s and determine refrigeration effect work input heat of rejection coefficient of performance water mass flow rate (Cp = 4.18 kJ/kgK) air mass flow rate (Cp = 1.02 kJ/kgK
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Can you Learning Outcomes At the end of this lecture you should be able to1. Describe the p-h chart and be able to represent the
cycle on this2. Describe the terms refrigeration duty, heat of rejection,
refrigeration effect, work input and coefficient of performance
3. Determine the refrigeration effect and coefficient of performance, work input of a simple refrigeration cycle on a pressure – enthalpy chart