SU821866A1 - Heliorefrigerating unit - Google Patents

Description

- The invention relates to the use of solar energy and can be applied when creating refrigerated areas intended for operation in B, the supply of which with other forms of energy besides solar is difficult or impossible. A well-known solar cooling installation comprises a heat-insulated chamber with a radiation receiver installed in it in the form of a container filled with a sorbent with refrigerant collectors located in it, made in the form of perforated pipes connected to an air condenser connected to a receiver through a refrigerant evaporator coupled to the refrigerating chamber 1, However, the use of a hot-box type with a large receiving surface in this solar cooling chamber leads to significant heat loss and a decrease in the solar energy utilization ratio ri of the overall efficiency of the solar cooling plant. It is also a disadvantage that when the solar radiation flux density is less than 600 W / k, the temperature required for evaporation of the refrigerant is not reached and, thus, the range of use of the solar cooling unit is reduced. The purpose of the invention is to increase efficiency and cooling capacity. The goal is achieved by the fact that the installation additionally contains concentrators with photoconverters in their focal planes, a heat distribution plate, an electrical accumulator and a refrigeration electrical unit with an additional refrigerant evaporator, the photoelectric converters installed on the heat distribution plate and connected to the electroaccumulator, the latter is connected to the refrigerating unit, and the photoconverter is connected to the heat distribution plate and is connected to the cooling accumulator, which is connected to the cooling accumulator, which is connected to the cooling accumulator, which is connected to the cooling accumulator, which is connected to the cooling casing, which is connected to the cooling casing, which is connected to the cooling casing, which is connected to the cooling casing, which is connected to the cooling casing and is connected to the cooling casing, which is connected to the cooling casing and is connected to the cooling casing, which is connected to the cooling casing and is connected to the cooling casing, which is connected to the cooling casing and is connected to the cooling system. its refrigerant evaporator is installed in the refrigerating chamber, and the perforated pipes are made of heat pipes one material and fixed on the heat distribution plate. Hubs can be made in the form of fokonov or foklinov. The drawing shows a scheme of solar cooling plant. The installation contains a heat-insulated chamber 1 with a radiation receiver installed in it in the form of a vessel 2 sealed with a sorbent and located in it refrigerant collectors. agent, made in the form of perforated pipes 3, connected to an air condenser 4 connected to a receiver 5, which is connected through a refrigerating chamber 7 through a refrigerant evaporator 6. The installation further comprises concentrators 8 with photoconverters 9 in their focal planes, a heat distribution plate 10, the electroaccumulator 11 and the refrigerating electrical unit 12 with an additional evaporator 13 of the refrigerant, with the photoconverters 9 installed on the heat distribution plate 10 and electrically connected to cumulative torus 11, the latter is connected to a refrigeration generating set 12. The evaporator 13, the refrigerant is installed in the cooling chamber 7 and the perforated pipes 3 made of heat conductive material and mounted on the heat distribution plate 10. The hubs 8 are formed as Fauconnier. Perforated pipes 3 are connected to an air condenser by means of a manifold. 1 Receiver 5 serves as a reservoir for a coolant — liquid ammonia. The lower part of ispatiteJt 6 is located in a tank 15 filled with water. The electric power produced by the photovoltaic cells 9 is transmitted through the collector wires 16 and accumulates in the electric accumulator 11, to which the concentrator orientation system 17 is connected. To reduce heat loss, the concentrators (focons) are evacuated or filled with 1-gas. To improve the optical characteristics of concentrators, their surface is covered with a selective coating.

Solar cooling installation works as follows.

During the insolation period, the solar radiation is concentrated with the help of concentrators 8 on the surface of the photoconverters 9. The generated electricity is stored in the electric accumulator 11. Heat from the photoconverters is transferred through the heat distribution plate 10 and the perforated pipes 3 to the sorbent. When reaching the working. temperature, a refrigerant is evaporated from the sorbent, which enters the collector 14 through perforated pipes. At the same time, the pressure in the chamber 1 increases. The refrigerant is liquefied in the air condenser 4 and flows into the receiver 5. At night, chamber 1 cools down and the pressure in it decreases. The liquid refrigerant, which extracts heat from the water in the tank 15, evaporates in the evaporator 6, re-enters the sorbent and is sorbed

On him. In this case, the water is frozen and serves to cool the refrigerating chamber 7 for a subsequent period up to a repeated cycle of water cooling. The electric power stored in the electric accumulator 11 is consumed to power the orientation system 17, which allows the installation to be tracked by the sun and thus make fuller use of the incoming solar radiation. In the absence of long-term solar radiation, the stored electric power is used to power the refrigerating electrical unit 12, the evaporator. 1.3 which is located in the common refrigerating chamber 7. In this way, the refrigerating chamber 7 is continuously cooled and maintained fully autonomous and solar cooling equipment from other energy sources.

0 The concentration of solar radiation using focons leads to a decrease in heat loss and an increase in the efficiency of the installation. In addition, the concentration of radiation allows

5, to obtain the necessary operating temperatures at a solar flux density of 300 W / m,

This makes it possible to increase the duration of the period of operation Q of the solar cooling plant during the year and thereby reduce its payback period.

Claims (2)

1. A solar-refrigeration plant comprising a heat-insulated chamber with a receiver receiving radiation in it in the form of a filled container sorbent with refrigerant collectors located in it, made in the form of perforated pipes connected to an air condenser connected to the receiver, which, through the refrigerant evaporator, is connected to the refrigerating chamber, which means that, in order to increase the efficiency and the cooling capacity, the installation further comprises concentrators with photoconverters in their focal planes, a heat distribution plate, an electrical accumulator and a refrigerating electrical unit with an additional refrigerant evaporator, the photoconverters are installed on the heat distribution plate and electrically connected to the electric accumulator, the latter is connected to the refrigerating electrical unit, its refrigerant evaporator is installed in the refrigerating chamber, and the perforated pipes are made of heat-conducting material and mounted on the heat distribution plate. 2. Installation under item 1, that is, so that KOHueHfpaTOpbi are made in the form of fokonov or foklinov. Sources of information taken into account in the examination 1. Shadiev O. Study of the solar household adsorption refrigerator.-Abstract of the thesis. Ashgabat, Institute of Chemistry LN TSSR, 1974.