SU1620788A1 - Device for pulse-width control of electromagnet - Google Patents

Abstract

The invention relates to refrigeration and can be used in those industries that require artificial cold of various parameters. The purpose of the invention is to increase the efficiency of work. The compression refrigerating machine is installed in the lower cooling stage, and the absorption refrigerating machine is installed in the upper cooling stage, while the generator 2 is additionally brought into thermal contact with the condenser 11 of the compression refrigerating machine before its thermal contact with the compressor 10 and the oil sump 19. When the unit is running, heat, allocated in the condenser 11, in the head 15 and the oil collector 19 of the compressor 10, is used to freeze the water-ammonia solution in the generator 2. 1 sludge.

Description

The invention relates to refrigeration, in particular to two-stage refrigeration units, and can be used in those industries where artificial cold of various 5 parameters is required.

The purpose of the invention is to increase the efficiency of the work.

The drawing shows a schematic diagram of a two-stage compression and absorption refrigeration unit.

The refrigeration unit comprises an absorption refrigeration machine, which includes an evaporator 1, a generator 2, a reflux condenser 3, a regenerative heat exchanger 4, an absorber 5, a condenser 6, a thermosyphon 7, 15 a gas heat exchanger 8, a receiver 9, and a compression refrigeration machine, which, in turn, includes a compressor 10, a condenser 11, a high temperature evaporator 12, a low temperature evaporator 13, a regenerative heat exchanger 14. The compressor contains a head 15. After the condenser, a control valve 16. is installed. compressors 10 connected to the discharge conduit 17 and to the suction side - 25 suction line 18. Compressor 10 is provided with a sump 19 to a heat exchanger 20 located inside the oil sump 19. The discharge line 17 is connected to the refrigerant condenser 11 which through control valve 16 soe- θ ³ dinene with high and low temperature evaporators 12 and 13. The refrigerant outlet from the low temperature evaporator 13 is connected through a regenerative heat exchanger 14 by a suction pipe 18 to a compressor 10. An absorber 2 ionic holo- spinning machine ³⁵ is shown in thermal contact with the condenser 11, a heat exchanger 20, the sump 19 and the head 15 of the compressor 10. In a thermosiphon 7 head 15 of the compressor 10 is connected with the pipeline 40 vodom regenerative heat exchanger 4 and reflux condenser 3. The output of the receiver 9 is connected to the generator 2.

The refrigeration unit operates as follows.

The compressor 10 compresses the refrigerant vapors 45, for example freon, and feeds them through a pipe 17 to the condenser 11, in which they condense with the removal of condensation heat to the generator 2 of the absorption refrigeration machine. The liquid refrigerant from the condenser 11 through the regenerative heat exchanger ⁵⁰ and the control valve 16 enters sequentially into the low and high temperature evaporators 13 and 12, in which it boils, producing a refrigerating effect: The vapors formed in this case are sucked out through the pipe 18 by compressor 10.

The heat generated in the condenser 11, in the head 15 and the oil collector 19 of the compressor 10, is used to evaporate the ammonia-water solution in the generator 2. The vapor-liquid emulsion formed in it passes through the Thermosiphon 7, after which it is separated into the vapor phase, sent to the reflux condenser 3, and the liquid phase (weak solution) going to the regenerative heat exchanger 4. After the reflux condenser 3, refrigerant vapor (ammonia) enters the condenser 6, in which they are condensed, and from it the liquid refrigerant through the gas heat exchanger 8 enters the evaporator spruce 1, in which the refrigerant evaporates at a low partial pressure in a hydrogen medium and produces cold. The resulting rich ammonia-hydrogen mixture through a gas heat exchanger 8 enters the absorber 5, into which a weak solution passes through the regenerative heat exchanger 4. In the absorber 5, the absorption of ammonia vapors takes place, a strong solution is discharged into the receiver 9, and the purified hydrogen mixture through the gas heat exchanger 8 goes to the evaporator 1.

Claims (1)

Claim A two-stage compression-absorption refrigeration unit containing a compression chiller with high and low temperature evaporators, a condenser, an oil sump, a compressor and a control valve, and an absorption chiller with its own condenser, thermosyphon, reflux condenser, heat exchanger-regenerator, evaporator, absorber and generator, having thermal contact with a compressor and an oil sump of a compression refrigerating machine, each of which is installed in the upper and lower her cooling steps, characterized in that, in order to improve the efficiency of work, the compression refrigeration machine is installed in the lower cooling stage and the absorption refrigeration machine is installed in the upper cooling stage, while the generator is additionally brought into thermal contact with the condenser of the compression refrigeration machine before its thermal contact with compressor and oil pan.