SU861892A1 - Absorption-ejection refrigerating plant - Google Patents

Description

(54) ABSORPTION AND EJECTOR REFRIGERATING

INSTALLATION

The invention relates to refrigeration engineering, in particular to absorption ejection refrigeration units. Absorption-ejector chillers are known, containing high and low pressure generators with lines of weak and strong solutions, a condenser installed after the high pressure generator with a liquid refrigerant pipe connected through the throttle valve to the evaporator, an absorber with a pump and an ejector whose working nozzle is connected to the steam cavity of the low-pressure generator, and the reception on the chamber — to the vapor cavity of the evaporator, and the heat exchanger-regenerator connected between the high-pressure generator and an absorber. However, such installations are not very economical, due to the insufficient use of the heat of a weak solution for heating a strong, directed evaporation into generators. The purpose of the invention is to increase efficiency. This goal is achieved by the fact that the installation is equipped with an additional heat exchanger-regenerator included in the line of weak and strong solutions between the low-pressure generator to the absorber. The drawing shows schematically the proposed installation. The installation has a high pressure generator 1, a low pressure generator 2, a weak solution line 3, a strong solution line 4, a condenser 5, a liquid refrigerant pipe 6, a throttle valve 7, an evaporator 8, an absorber 9, a pump 10 ,. an ejector 11 with a working nozzle 12 and a receiving chamber 13, a heat exchanger-regenerator 14 and an additional heat exchanger-regenerator 15. In addition, the installation contains throttle valves 16 and 17, respectively, on weak solutions of the high-pressure generator and the low-pressure generator 2, water subcooler 18 liquid refrigerant and reflux condenser 1

The installation works as follows. In the high pressure generator 1, external coolant separates refrigerant vapor from the solution with a small admixture of absorbent vapor. In a reflux condenser 19, the absorbent vapor condenses and flows back into the boiling solution, and the clean refrigerant vapor enters the condenser 5, which is liquefied with running water. The liquid refrigerant through the pipeline 6 flows through the water desuperheater 18 and the throttle valve 7 into the evaporator 8, in which it boils at low pressure, producing a refrigerating effect. The resulting vapors from the evaporator are sucked off by the ejector 11. At the same time, the vapors enter the receiving chamber 13 of the ejector, into the working nozzle 12 of which refrigerant vapor separated from the solution in the low pressure generator 2 is fed. The whole vapor mixture after compression in the ejector I1 is absorbed by the solution in the absorber 9. The resultant strong solution is taken up by pump 10 and is fed through line 4 of the strong solution partly through heat exchanger generator 14 to high pressure generator 1 and the remaining part through heat exchanger regenerator 15 to low pressure generator 2. The weak solution from generator 2 through line 3 is fed through the second cavity of the heat exchanger-regenerator 15 and the throttle valve 17 to the absorber 9. It is also fed through the heat exchanger-regenerator 14 and the throttle valve 16

evaporated solution from generator 1. Thus, the circulation of solutions and coolant in the proposed installation is completed.

The proposed installation allows to reduce the consumption of heat for the production of cold, as well as low potential waste heat can be used to evaporate the solution in high and low pressure generators.

Claims (1)

1. USSR author's certificate 117192, cl. F 25 B 15/02, 1958.