Unit-V

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UNIT V REFRIGERATION AND AIR CONDITIONING:

UNIT V REFRIGERATION AND AIR CONDITIONING

Refrigeration:

Refrigeration It is defined as the process of providing and maintaining a temperature well below that of surrounding atmosphere. In other words refrigeration is the process of cooling substance.

Refrigerators and heat pumps:

Refrigerators and heat pumps If the main purpose of the machine is to cool some object the machine is named as refrigerator If the main purpose of machine to heat a medium warmer than the surroundings, the machine is termed as heat pump.

Refrigerator and Heat pump:

Refrigerator and Heat pump Q R Work Input Q R Work Input Heat Pump Warm Space Cold Space Refrigerator

Types of Refrigerators:

Types of Refrigerators Ice Refrigerators : Ice is kept in the cabinet of refrigerators and this acts as the refrigerating means. Air Refrigerators : Air is used as working agent in these types of refrigerators. E.g., Bell Coleman Cycle. Vapour Refrigerators: The working agents employed in this type of refrigerators are ammonia, CO 2, SO 2, freons etc.,

Applications of Refrigeration:

Applications of Refrigeration In chemical industries, for separating and liquefying the gases. In manufacturing and storing ice. For the preservation of perishable food items in cold storages. For cooling water. For controlling humidity of air manufacture and heat treatment of steels. For chilling the oil to remove wax in oil refineries. For the preservation of tablets and medicines in pharmaceutical industries. For the preservation of blood tissues etc., For comfort air conditioning the hospitals, theatres, etc.,

Vapour Compression Refrigeration System:

Vapour Compression Refrigeration System

Vapour Compression Refrigeration System - Construction:

Vapour Compression Refrigeration System - Construction This system consists of a compressor, condenser, a receiver tank, an expansion valve and an evaporator. Compressor : Reciprocating compressors generally used. For very big plants centrifugal compressors directly coupled with high speed rotating engines (gas turbine) are used.

Vapour Compression Refrigeration System - Construction:

Vapour Compression Refrigeration System - Construction Compressor: For very big plants Centrifugal compressors directly coupled with high speed rotating engines (gas turbine) are used

Vapour Compression Refrigeration System - Construction:

Vapour Compression Refrigeration System - Construction Condenser : It is a coil of tubes made of copper. Receiver tank: It is the reservoir of liquid refrigerant. Expansion Valve: This is a throttle valve. High pressure refrigerant is made to flow at a controlled rate through this valve. Evaporator : It is the actual cooler and kept in the space to be cooled. The evaporator is a coil of tubes made of copper

Vapour Compression Refrigeration System - Working:

Vapour Compression Refrigeration System - Working Working : The low pressure refrigerant vapour coming out of the evaporator flows into the compressor. The compressor is driven by a prime mover. In the compressor the refrigerant vapour is compressed. The high pressure refrigerant vapour from the compressor is then passed through the condenser. The refrigerant gives out the heat it had taken in the evaporator (N)

Vapour Compression Refrigeration System - Working:

Vapour Compression Refrigeration System - Working Working : 6. The heat equivalent of work done on it (w) on the compressor. 7. This heat is carried by condenser medium which may be air or water. 8. The high pressure liquid refrigerant then enters the expansion valve. 9. This valve allows the high pressure liquid refrigerant to flow at a controlled rate into the evaporator. 10. While passing though this valve the liquid partially evaporates.

Vapour Compression Refrigeration System - Working:

Vapour Compression Refrigeration System - Working Working : 11.Most of the refrigerant is vapourised only in the evaporator, at a low pressure. 12. In the evaporator the liquid refrigerant absorbs its latent heat of vapourisation from the material which is to be cooled. 13. Thus the refrigerating effect (N) is obtained. 14. Then the low pressure refrigerant enters the compressor and the cycle is repeated.

Vapour Absorption Refrigeration system:

Vapour Absorption Refrigeration system In this system compression process of vapour compression cycle is eliminated. Instead of that the following three processes are carried out. Absorbing ammonia vapour into water. Pumping this solution to a high pressure cycle Producing ammonia vapours from ammonia solution by heating.

Vapour Absorption Refrigeration system - Construction:

Vapour Absorption Refrigeration system - Construction Construction: The vapour absorption system consists of a condenser, an expansion valve and an evaporator. They perform the same as they do in vapour compression method. In addition to these, this system has an absorber, a heat exchanger, an analyser and a rectifier.

Vapour Absorption Refrigeration system - Construction:

Vapour Absorption Refrigeration system - Construction Working: Dry ammonia vapour at low pressure passes in to the absorber from the evaporator. In the absorber the dry ammonia vapour is dissolved in cold water and strong solution of ammonia is formed. Heat evolved during the absorption of ammonia is removed by circulating cold water through the coils kept in the absorber. The highly concentrated ammonia (known as Aqua Ammonia ) is then pumped by a pump to generator through a heat exchanger.

Vapour Absorption Refrigeration system - Construction:

Vapour Absorption Refrigeration system - Construction Working: 6. In the heat exchanger the strong ammonia solution is heated by the hot weak solution returning from the generator to the absorber. 7. In the generator the warm solution is further heated by steam coils, gas or electricity and the ammonia vapour is driven out of solution. The boiling point of ammonia is less than that of water. Hence the vapours leaving the generator are mainly of ammonia.

Vapour Absorption Refrigeration system - Construction:

Vapour Absorption Refrigeration system - Construction Working: 9. The weak ammonia solution is left in the generator is called weak aqua. 10. This weak solution is returned to the absorber through the heat exchanger. 11. Ammonia vapours leaving the generator may contain some water vapour. 12. If this water vapour is allowed to the condenser and expansion valve, it may freeze resulting in chocked flow. 13. Analyser and rectifiers are incorporated in the system before condenser.

Vapour Absorption Refrigeration system - Construction:

Vapour Absorption Refrigeration system - Construction Working: 14. The ammonia vapour from the generator passes through a series of trays in the analyser and ammonia is separated from water vapour. 15. The separated water vapour returned to generator. 16. Then the ammonia vapour passes through a rectifier. 17. The rectifier resembles a condenser and water vapour still present in ammonia vapour condenses and the condensate is returned to analyser. 18. The virtually pure ammonia vapour then passes through the condenser.

Vapour Absorption Refrigeration system - Construction:

Vapour Absorption Refrigeration system - Construction Working: 19. The latent heat of ammonia vapour is rejected to the cooling water circulated through the condenser and the ammonia vapour is condensed to liquid ammonia. 20. The high pressure liquid ammonia is throttled by an expansion valve or throttle valve. 21. This reduces the high temperature of the liquid ammonia to a low value and liquid ammonia partly evaporates. 22. Then this is led to the evaporator. 23. In the evaporator the liquid fully vaporizes.

Vapour Absorption Refrigeration system - Construction:

Vapour Absorption Refrigeration system - Construction Working: 24. The latent heat of evaporation is obtained from the brine or other body which is being cooled. 25. The low pressure ammonia vapour leaving the evaporator again enters the absorber and the cycle is completed. 26. This cycle is repeated again to provide the refrigerating effect.

Comparison between Vapour compression & Vapour Absorption refrigeration systems:

Comparison between Vapour compression & Vapour Absorption refrigeration systems S.No . Vapou r Compression System Vapour Absorption System 1 This system has more wear and tear and produces more noise due to the moving parts of the compressor. Only moving part in this system is an aqua pump. Hence the quieter in operation and less wear and tear 2. Electric power is needed to drive the system Waste of exhaust steam may be used. No need of electric power 3. Capacity of the system drops rapidly with lowered evaporator pressure Capacity of the system decreases with the lowered evaporative pressure, by increasing the steam pressure in generator. 4. At partial loads performance is poor. At partial loads performance is not affected. 5. Mechanical energy is supplied through compressor Heat energy is utilised 6. Energy supplied is ¼ to ½ of the refrigerating effect Energy supplied is about one and half times the refrigerating effect

Comparison between Vapour compression & Vapour Absorption refrigeration systems:

Comparison between Vapour compression & Vapour Absorption refrigeration systems S.No . Vapou r Compression System Vapour Absorption System 7. Charging of the refrigerating to the system is easy Charging of refrigerant is difficult 8. Preventive measure is needed, since liquid refrigerant accumulated in the cylinder may damage to the cylinder Liquid refrigerant has no bad effect on the system.

Definitions:

Definitions Refrigerating Effect (N): It is defined as the quantity of heat extracted from a cold body or space to be cooled in a given time. N= Heat extracted from the cold space Time taken Specific Heat of water and ice : It is the quantity of heat required to raise or lower the temperature of one kg of water (or ice), through one kelvin or (1 0 c) in one second. Specific heat of water, C pw = 4.19 kJ/kg K Specific heat of ice, C pice = 2.1 kJ/kg K.

Definitions:

Definitions Capacity of a Refrigeration Unit : Capacity of a refrigerating machines are expressed by their cooling capacity. The standard unit used for expressing the capacity of refrigerating machine is ton of refrigeration. One ton of refrigeration is defined as, “the quantity of heat abstracted (refrigerating effect) to freeze (into ice) one ton of water in a duration of 24 hours at 0 o c”. Heat extracted from at o o c = latent heat of ice Latent heat of ice = 336 kJ/kg i.e., 336 kJ of heat should be extracted one kg of water at 0 o C to convert it into ice.

One ton of Refrigeration:

One ton of Refrigeration One ton of refrigeration= 336x1000 kJ/24 hrs. = 336x1000 kJ/min 24x60 One ton of refrigeration = 233.333 kJ/min = 3.8889 kJ/sec For calculation purpose, One ton of refrigeration = 12600 kJ/hr = 210 kJ/min Ton of refrigeration = 3.5 kJ/s

Definitions - COP:

Definitions - COP Performance of Refrigerators (Co efficient of Refrigerators) : The performance of heat engine is expressed by its thermal efficiency. The performance of a refrigerator cannot be expressed in terms of efficiency. In case of a refrigerator the aim is to extract maximum quantity of heat from the sink with minimum of work input. Hence a new term Co efficient of Performance is brought into use to express the performance of refrigerator.

Definitions - COP:

Definitions - COP Co efficient of Performance: It is defined as the ratio of heat extracted in a given time (refrigerating effect) to the work input. Co efficient of performance = Heat extracted in evaporator Work Input Co efficient of performance = Refrigerating Effect Work Input Co efficient of performance = N W The COP is always greater than 1 and known as theoretical coefficient of performance.

Layout of Domestic Refrigerator:

Layout of Domestic Refrigerator

Window Type Air Conditioner:

Window Type Air Conditioner

Window Type Air Conditioner - Construction:

Window Type Air Conditioner - Construction This is also called room air conditioner. This unit consists of the following. A cooling system to cool and dehumidify the air involves a condenser, a compressor and a refrigerant coil. A filter to any impurities in the air. The filter is made of mesh, glass wool or fibre . A fan and adjustable grills to circulate the air. Controls to regulate the equipment operation.

Window Type Air Conditioner - Working:

Window Type Air Conditioner - Working The low pressure refrigerant vapour is drawn from the evaporator to the hermetic compressor through suction pipe. It is compressed from low pressure to the high pressure and supplied to the condenser. It is condensed in the condenser by passing the outdoor air over the condenser coil by a fan. The liquid refrigerant is passed through the capillary into the evaporator.

Window Type Air Conditioner - Working:

Window Type Air Conditioner - Working 5. In the evaporator the liquid refrigerant picks up the heat from the refrigerator surface and gets vaporized. 6. A motor driven fan draws air from the room through the air filter and this air is cooled by losing its heat to the low temperature refrigerant and cold air is circulated back into the room. 7. The vapour refrigerant from the evaporator goes to the compressor from evaporator and the cycle is repeated. 8. Thus the room is air conditioned

Window Type Air Conditioner - Working:

Window Type Air Conditioner - Working 9. The quantity of air circulated can be controlled by the dampers. 10. The moisture in the air passing over the evaporator coil is dehumidified and drips into the trays. 11. This water evaporator to certain extent and thus helps in cooling the compressor and condenser. 12. The unit automatically stops when the required temperature is reached in the room. This is accomplished by the thermostat and control panel.

Split Type Air Conditioner - Construction:

Split Type Air Conditioner - Construction

References:

References www.phac-aspc.gc.ca/.../section3-eng.php Shanmugam G and Palanichamy M S, “Basic Civil and Mechanical Engineering”,Tata McGraw Hill Publishing Co., New Delhi, (1996). Ramamrutham. S, “Basic Civil Engineering”, Dhanpat Rai Publishing Co. (P) Ltd. (1999). Seetharaman S. “Basic Civil Engineering”, Anuradha Agencies, (2005). Venugopal K and Prahu Raja V, “Basic Mechanical Engineering”, Anuradha Publishers, Kumbakonam, (2000).

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