SU1101636A1 - Helium-absorption refrigerating unit - Google Patents

Abstract

HELIOABSO1 BONIC REFRIGERANT INSTALLATION, containing a generator installed in the circulation circuit of the solution, made in the form of an inclined surface heated by solar energy, on which a sprinkler of a weak solution is installed, and placed above this surface with the formation of a channel for air passage and water vapor released from a solution and a transparent screen , characterized in that, in order to improve efficiency by increasing the amount of air blown in the opposite direction of the wind, the screen in the a-zone is located and the sprinkler has a cutout, over which a profile sheet is additionally installed, which forms an ejector with a screen with a working platform located in front of the cutout, a receiving chamber — at the location of the latter and a diffuser — after the cutout. . 2/7

Description

The invention relates to refrigeration engineering, in particular to helio-absorption chillers of bFibiM installations.

Gel-absorption refrigeration units are known that contain a generator installed in the circulation circuit of the generator, made in the form of a heated solar energy-inclined surface, on which a weak solution sprinkler is installed, and placed above this surface with the formation of a channel for the passage of air and water vapor released from the solution. transparent screen 1.

A disadvantage of the known installations is their low efficiency, due to the weak draft of the air through the generator in the opposite direction of the wind.

The purpose of the invention is to increase efficiency by increasing the amount of air blown in the opposite direction of the wind.

This goal is achieved by the fact that in a Helioabsorption refrigeration installation containing a generator installed in the circulation circuit of a generator, made in the form of an inclined surface heated by solar energy, on which a sprinkler of a weak solution is installed, and placed above this surface with the formation of an air passage and water vapor from a solution of water vapor; a transparent screen, the latter in the area where the irrigator is located has a cut-out above which a profile sheet is additionally installed, forming a screen With an ejector with a working nozzle located in front of the notch, a receiving chamber — at the location of the latter, and a diffuser — after the notch.

The drawing shows schematically the proposed installation.

The installation includes a generator 1, made in the form of an inclined surface 2 heated by solar energy, on which the irrigator 3 is installed a weak solution.

and a transparent screen 4 placed above this surface 2, forming with channel 2 a channel 5 for the passage of air and refrigerant vapor evaporating from a solution, a profile sheet 6 forming with an screen 4 an ejector having a working nozzle 7, a receiving chamber 8 and a diffuser 9. In addition to the installation also contains a heat exchanger regenerator 10, an absorber 11 placed in one housing 12 with an evaporator 13, a pump

14 and a vacuum pump 15.

The installation works as follows. The pump 14 takes the weak solution from the absorber 11 and pumps it through the heat exchanger-regenerator 10 into the irrigator 3, from which the solution is distributed and drains along the inclined surface 2. Here, under the action of solar energy, the solution evaporates and becomes strong, and the evaporating coolant (water ) along with the purged air are removed through

0 channel 5 and the ejector diffuser 9 into the surrounding atmosphere. The strong solution from the surface 2 of the generator 1 is discharged through the heat exchanger-regenerator 10 again into the absorber, in which it absorbs the refrigerant vapor leaving the evaporator 13, and becomes weak. With a headwind, air is ejected with refrigerant vapor from channel 5, which increases the evaporative capacity of the solution flowing over surface 2, which improves the performance of the plant as a whole. In this case, the wind flow of air in. Enters the working nozzle 7 of the ejector, ejects a mixture of air with refrigerant vapor in the receiving chamber and pumps the specified mixture into the environment through the diffuser 9.

The economic efficiency of the proposed plant is expressed in a reduction in capital and operating costs, due to an increase in the average cooling capacity of the plant during the operation period.

Claims (1)

A HELIOBABLATION REFRIGERATING UNIT containing a generator installed in the circulation circuit of the solution, made in the form of an inclined surface heated by solar energy, on which a sprinkler of a weak solution is mounted, and placed above this surface with the formation of a channel for air passage and water vapor released from the solution, which differs the fact that, in order to increase efficiency by increasing the amount of purged air in the opposite direction of the wind, the screen in the area of the carrier has a cut-out, over which a profile sheet is additionally installed, forming an ejector with a screen with a working nozzle located in front of the cut-out, a receiving chamber in the place of the latter and a diffuser after the cut-out.