SU1726928A1 - Refrigerating plant - Google Patents

Abstract

The invention relates to refrigeration engineering and is intended for use in cooling systems. The aim of the invention is to improve the economy. The refrigeration unit contains a compressor 1, the output of which is connected via a condenser 2 to the nozzle inlet of a vortex ejector 4, and the entrance to the compressor is connected to the axial zone of the vortex chamber 3 of the vortex ejector 4, the suction nozzle of which is connected to the vapor cavity 5 of the evaporator 6, and the additional liquid collector 7 through the pump 8 is connected to the cooled object 9, the output of which is connected to the vapor cavity 5 of the evaporator 6, and in the area of the peripheral exit of the vortex chamber 3 there is a deflector 10, made in the form of a cylindrical erhnosti forming a vortex chamber housing 3 slit 11 for separating the liquid phase refrigerant into the cavity 12 which through a throttle 13 is connected to a further collector 7 liquid. 1 hp f-ly, 1 ill. (Ls

Description

The invention relates to refrigeration technology, as well as to installations using a vortex cooling effect.

A steam compressor refrigeration unit is known, comprising a compressor, a condenser, an expansion device, an evaporator, a pump, and a consumer cold.

A disadvantage of the known installation is the complexity and low reliability.

Closest to the proposed is a refrigeration unit, containing an expansion device in the form of a vortex tube, cooled by water, the inlet of which through the condenser is connected to the outlet of the compressor, and its output to the cold consumer.

A disadvantage of the known refrigeration unit is low efficiency due to incomplete use of the energy of the compressed refrigerant.

The purpose of the invention is to increase efficiency.

This is achieved by the fact that in a refrigeration unit containing a compressor, a condenser, an evaporator, a pump and a cold consumer, the expansion device is designed as a vortex ejector, the suction nozzle of which is connected to the evaporator, the axial output of its vortex chamber is connected to the compressor inlet, and its peripheral output communicated through the throttle with an additional collection of liquid, the output of which is connected to the pump inlet. Swirl Ejector

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but contains a deflector installed in the area of the peripheral exit of the vortex chamber.

The drawing shows a diagram of the refrigeration unit.

The refrigeration unit contains a compressor 1, the output of which is connected via condenser 2 to the nozzle inlet of the vortex ejector 4, and the entrance to the compressor is connected to the axial zone of the vortex chamber 3 of the vortex ejector 4 installed in the area of the peripheral output of the vortex chamber 3. The suction nozzle of the vortex ejector 4 is connected to vapor cavity 5 of the evaporator 6. Additional collection 7 of the liquid through the pump 8 is connected to the cooled object 9, the output of which is connected to the vapor cavity 5 of the evaporator 6. The evaporator 6 and the additional collection 7, the fluid communicated between them.

, In the area of the peripheral exit of the vortex chamber 3, a deflector 10 is placed, made in the form of a cylindrical surface, which forms a slit 11 with the body of the vortex chamber 3 for collecting the liquid phase of the refrigerant. The peripheral cavity 12 of the collection of the liquid phase through the choke 13 is connected to the additional collector 7.

The installation works as follows.

The refrigerant compressed in compressor 1 enters the condenser 2 where it is cooled to complete condensation, and in the liquid phase the compressed refrigerant enters the inlet to the nozzle inlet of the vortex ejector 4 and further into the vortex chamber 3 in the form of an intensely swirling vortex flow moving from a nozzle inlet to the deflector 10. In the axial area of the nozzle inlet, a reduced pressure zone is created, which is connected to the vapor space 5 of the evaporator 6. The condensed liquid in the vortex chamber 3 collects through the slot 11 in the cavity 12 of the deflector 10. Ots Departed, the liquid phase of the refrigerant, having expanded at the throttle 13, enters the liquid collector 7. The refrigerant from the collector 7 is pumped through the pump 8 through the cooled object 9, where it performs the necessary heat removal. Steam refrigerant vapor phase

5, the vortex ejector is pumped through the axial zone of the vortex chamber 3 and enters the entrance to the compressor 1. At the same time, a reduced pressure is maintained in the vapor cavity 5 of the evaporator 6, and therefore a lower refrigerant temperature is achieved due to a higher degree of expansion of the refrigerant system vortex tube choke. The vapor phase pumped through the vortex chamber participates in the process of heat and mass transfer intensity with coolant elements entering the vortex chamber 3 through the nozzle device of the vortex ejector 4. As a result, the peripheral masses of the refrigerant are cooled. Thus, the vortex chamber contributes to the utilization of the coolant from the vapors that have worked in the evaporator and

the cooled object 9. The condensed and supercooled liquid phase of the refrigerant is separated on the walls of the vortex chamber 3 and taken through the slit 11 into the collection cavity of the liquid phase 12, from where it

is supplied expanding at throttle 13. During the expansion process, the temperature of the refrigerant further decreases and in this supercooled state the refrigerant enters the evaporator 6, where the vapor phase

separates from the liquid and the cycle repeats.

Claims (2)

1. Refrigeration unit containing compressor, condenser, expansion vessel a device, also an evaporator, a pump, and a cold consumer, characterized in that, in order to increase efficiency, the expansion device is designed as a vortex ejector, the nozzle of which is connected to the evaporator, the axial output of its vortex chamber is connected to the compressor inlet, and its peripheral output is communicated through the throttles with an additional fluid collector, the output of which is connected to the pump inlet. 2. The apparatus according to claim 1, wherein the vortex ejector further comprises a reflector installed in the zone of the peripheral exit of the vortex chamber.