RU2030697C1 - Test stand for hermetic refrigeration compressor - Google Patents

Abstract

FIELD: refrigerating engineering. SUBSTANCE: stand has additional water-ammonia circuit. Section 9 of circuit has two heat exchangers for circulating strong and weak water-ammonia solutions, and generator 10. Control of operation of khladon and water-ammonia circuits is provided by control valves B1-B9. Stand provided simulating of operation of separate units of absorption-compression refrigerating set, testing of generator with simultaneous simulation of different operating conditions and design version of refrigerating set, makes it possible to study influence of compressor cooling on characteristics of compression circuit and influence of heat exchange on characteristics of absorption circuit. Stand is ecologically oriented. EFFECT: enhanced reliability of operation. 1 dwg

Description

 The invention relates to refrigeration, in particular to stands for testing hermetic compressors of domestic refrigeration machines.

 A known bench for testing the generator of absorption-diffusion domestic refrigerator.

 The disadvantage of this stand is the inability to test the compressor of a domestic refrigerator operating in a cycle with an absorption apparatus.

 There is also a bench for testing a sealed compressor in a domestic refrigerator.

 The disadvantage of this stand is the inability to test the compressor associated with the absorption refrigeration unit in the conditions of supplying part of the working fluid from it to the compressor.

 In addition, these stands do not allow testing by modeling thermal processes in the elements of the stands in the entire range of operating temperatures and pressures.

 The famous booth is accepted by the authors as a prototype.

 The aim of the invention is to expand the functionality of the bench for testing a sealed compressor.

 This goal is achieved in that the stand additionally contains a shell-and-tube water-ammonia circuit, the heat exchanger of which has a branch at the outlet, one branch of which is connected through the heat exchanger to the water-ammonia circuit generator, and the other to the compressor cooler coil inlet pipe, the outlet pipe of which is connected to the input of the control valve, one from the outputs of which it is connected to the input to the generator, and the other to the shell-and-tube heat exchanger of the water-ammonia circuit.

 The drawing shows a schematic diagram of the stand. The stand consists of a refrigerant circuit, which contains a compressor 1, a calorimeter 2, a thermostatic valve, a filter drier 4, an oil concentration measuring device 5, a receiver 6, a water condenser 7. An oil cooler coil 8 is built into the compressor 1. The absorption circuit contains section 9, consisting of two heat exchangers through which strong and weak water-ammonia solutions pass, a generator 10, a shell-and-tube heat exchanger 11, where condensate of low concentration is formed, and a shell-and-tube heat exchanger 12, in which ensiruetsya strong water-ammonia solution. The connection of the oil cooler coil 8 of the compressor 1 to the water-ammonia circuit is carried out using nozzles 13, 14. The water-ammonia solution is supplied to the oil cooler coil 8 through branching 15. There is a control valve 16 on the line of the oil cooler 8 and generator 10, which is connected to the pipelines using the pipes 17, 18, 19. Regulation of the operating modes of the HFC and water-ammonia circuits is carried out using control valves B1-B9.

 The stand works as follows.

 The compressor 1 pumps the refrigerant into the water condenser 7, from where the liquid flows into the receiver 6. The constant boiling pressure in the evaporator located in the calorimeter 2 is maintained by means of a heat control valve 3. The lower part of the calorimeter is filled with a secondary refrigerant, into which the electric heater is immersed. Freon-12 is used as a secondary refrigerant (regardless of which refrigerant the compressor is running on). The steam generated during boiling condenses on the outer surface of the evaporator of calorimeter 2. During the test, the power of the heater is controlled so that the pressure of the secondary refrigerant remains constant, i.e. so that the amount of cold received is equal to the amount of heat supplied. An instrument 5 for determining concentration is included in the liquid line.

 Strong aqueous ammonia solution from the shell-and-tube heat exchanger 12 of the absorption circuit enters through branching 15 into section 9 and the oil cooler coil 8. Here, the working fluid is heated due to the high temperature of the oil and evaporates.

 Under conditions of incomplete evaporation and the oil cooler coil 8, the working fluid is supplied through the pipe 17 to the inlet of the generator 10. With full evaporation, the working fluid is supplied through the pipe 18 to the inlet of the shell-and-tube heat exchanger 11. The supply of the working fluid through the pipes 17, 18 is carried out by a control valve 16.

Thus, the implementation of the bench for testing the compressor allows you to:
to simulate the operation of individual elements of an absorption and compression refrigeration unit;
to test the generator while simulating various operating conditions and design of the refrigeration unit;
to study the effect of compressor cooling on the characteristics of the compression circuit and the effect of heat transfer on the characteristics of the absorption circuit.

 Calculations show, and experiments confirm that the stand design proposed by the authors is efficient and environmentally sound.

 The calculation of economic efficiency is given below.

 Using this stand design, models of absorption-compression type refrigeration units have been developed that have passed heat and power tests. As a result, it was found that the energy intensity of these models is 8-10% lower than the total power consumed by the refrigerators of the basic Crystal and Minsk models.

Efficiency is determined from the expression
E = W ˙ n ˙ A ˙ C - 3, where W is the energy consumption of the base model,
n is the percentage reduction in energy consumption,
A is the annual output,
C is the cost of 1 kWh of electricity,
З - additional capital costs.

Claims (1)

 STAND FOR TESTING A SEALED REFRIGERATING COMPRESSOR, comprising a condenser, calorimeter, filter drier, an oil concentration measuring device and a throttle valve, characterized in that the stand further comprises a water-ammonia circuit, the shell-and-tube heat exchanger of which has a branch at the outlet, one branch of which is connected through a heat exchanger through one branch to the generator of the water-ammonia circuit, and the other to the inlet pipe of the compressor cooler coil, the outlet pipe of the latter is connected to the input of the control valve, and one of the valve outputs is connected to the input to the generator, and the other to the additional shell-and-tube heat exchanger of the water-ammonia circuit.