SU718672A1 - Helium-absorption refrigerating unit and method of operating same - Google Patents

Description

The invention relates to the field of refrigeration, as well as to solar absorption refrigeration units and methods for their operation.

Known solar absorption refrigeration units containing an inclined solar generator such as a hot box, purged in the zone of dripping of the evaporated solution with ambient air, and a heat regenerator between hot and cold solutions [1].

A disadvantage of the known installations is their low efficiency due to the lack of a heat accumulator in the exhaust hot air.

Known methods of operation of a solar absorption refrigeration unit by evaporating a solution while exposing it to solar radiation and ambient air and subsequent heat exchange between hot and cold solutions, the latter of which are sent to evaporation [1].

A disadvantage of the known methods is their low cost.

The aim of this invention is to increase the efficiency of the installation.

This goal is achieved in that the installation further comprises a heat accumulator included in the communication line of the generator re2 with the generator, the generator being provided with a discharge duct, and the battery is located in the latter and has a bypass line.

⁵ In order to increase the cost-effectiveness of the known method, during the period of high intensity of solar radiation, the heat of the air leaving the solution after blowing it is accumulated, and the accumulated heat ^{10 is} used to evaporate the solution during a period of insufficient intensity of solar radiation.

The drawing schematically shows the described installation, in which ¹⁵ carry out the proposed method.

The installation comprises an inclined solar generator 1 with a drip zone 2 of the evaporated solution 3, purged with ambient air 4, a regenerator ²⁰ between hot and cold solutions, a heat accumulator 6, an exhaust duct 7, a bypass line 8, a fan 9, a transparent screen 10, an air damper 11, weak solution pipe 12, ²⁵ strong solution collector 13, absorber 14, weak solution pump 15, evaporator 16, valves 17 and 18.

The installation is as follows.

Flock 3 in a heated solution of hydrochloric ^'1 finite radiation generator 1' simultaneously purged with pomoTtsyu vent'iyyatora 9 surrounding air 4. In this solution boils and paf'Y hYaDagonta formed together with the heated air flows into the air duct 7 (water) in which contains the battery 6, accumulating heat from the air-steam mixture. The evaporated (strong hot solution) is collected in a collector 13, from where it is directed through the regenerator 5 to the absorber 14, in which it absorbs the vapor of the refrigerant boiling in the evaporator 16. The weak solution formed in the absorber 14 is again pumped through the regenerator 5 through the regenerator 5 to the generator 1. With a high intensity of solar radiation, a weak solution is supplied through a valve 18 AND a bypass line 8 directly to the generator 1. When the intensity of solar radiation decreases, a weak solution enters the generator 1 through a valve 17 and a kumulyator 6. Cost-effectiveness of proposals expressed in a more rational use of solar izLuchopPya for the production of cold.

Claims (2)

Claim 1. Gelioabsorbtsionnaya refrigeration system comprising obliquely raspolozhen4 ny solar generator type hot box, purged with a dripping zone solution was evaporated ambient air and warm the regenerator between the hot and ho lodnym solutions ^5, characterized in that, in order to increase efficiency, further comprising a battery ustanoNKa heat included in the communication line of the regenerator with the generator, and ^{10 the} generator is equipped with a discharge duct, and the battery is located in the latter and has a bypass line. 2. The method of operation of the solar absorber installation according to π. 1 by evaporation of a solution with simultaneous exposure to it by solar radiation and ambient air and subsequent heat exchange between hot and cold solutions, the last of which is directed to evaporation ²⁰ , characterized in that during a period of high intensity of solar radiation the heat of the air leaving after blowing it solution, accumulate, and the accumulated heat is used for ²⁵ evaporation of the solution during a period of insufficient intensity of solar radiation.