RU2073819C1 - Cooling plant - Google Patents

Abstract

FIELD: refrigerating engineering; cooling with natural cool air. SUBSTANCE: plant has insulated refrigerating chamber and cold accumulator which contains hermetic reservoir filled with freezing liquid and device for transfer of heat from refrigerating chamber to accumulator; this device has tubular coolant carriers whose one part is located in reservoir of accumulator and other part is located in refrigerating chamber. Device for cooling the liquid in accumulator has tubular coolant carriers whose lower portion is located in reservoir of accumulator and upper portion is located outside it for contact with natural atmospheric air. Each coolant carrier has vertical extended metal housing with flexible walls; housing is filled with liquid at freezing point below the maximum possible negative temperature of natural atmospheric air. Reservoir of accumulator is heat-insulated and is located above refrigerating air. EFFECT: enhanced efficiency. 2 cl, 2 dwg

Description

 The invention relates to refrigeration in which naturally cold air is used.

 A battery cooler is known for accumulating cold in winter and cooling liquid in warm time, in which in the winter time in the freezing mode the cold outside air circulates through the pipes of the freezing installation, it freezes ice on the outer surfaces of the vertical pipes and horizontal pipes open at the top for cold air to access pipes dipped in water. As a cold-transporting liquid, water is used, which is circulated through a pump through a refrigerator, a heat exchanger and a cold accumulator (ed. St. USSR N 1615497, class F 25 D 3/00, 05/18/08).

 A disadvantage of the known device lies in the complexity of the design and in the large consumption of electricity necessary to ensure the circulation of the cold-transfer fluid and to ensure heat transfer. In addition, the known device does not allow to obtain a negative temperature in the refrigerator, since it uses the latent heat of melting ice. Moreover, the duration of the use of accumulated cold for a given volume of the refrigerating chamber is determined only by the volume of the chamber of the cold accumulator, which does not always allow you to increase the duration of the use of accumulated cold.

 Thus, the known installation for cooling as a result of its implementation does not allow to achieve a technical result, which consists in simplifying the design, in reducing the amount of electricity consumed, in increasing the duration of use of the accumulated cold.

 Closest to the proposed one is a cooling installation comprising a thermally insulated chamber, a cold accumulator capacity filled with a freezing liquid, means for transferring heat from the refrigerating chamber to the accumulator, including tubular coolants, one part of which is located in the accumulator container and the other in the refrigeration chamber, means for cooling the liquid in the cold accumulator. At the same time, the means for cooling the liquid in the battery contains thermosyphons, and the tubular coolants for transferring heat from the chamber to the battery are made in the form of a closed circuit with a pump installed in it. (Aut. St. USSR N 1763820, class F 25 D1 / 00, F 25 D 7/00, 09/23/92).

 A disadvantage of the known installation is the complexity of the design and the large energy consumption necessary to ensure the forced circulation of the cold fluid in the heat exchanger. In addition, the use of thermosiphons as a means for cooling the liquid in the capacity of the cold accumulator provides cooling the liquid by direct contact with the outside air. As a result, the temperature of the freezing liquid of the tank is directly dependent on the magnitude and duration of the negative outside temperature, which reduces the duration of use of the accumulated cold. In this case, the duration of use of the accumulated cold is determined by the capacity of the cold accumulator.

 Thus, the known installation for cooling during its implementation does not allow to achieve a technical result, which consists in simplifying the device, in reducing energy consumption and in increasing the duration of use of the accumulated cold.

 The present invention solves the problem of creating an installation for cooling, which allows its implementation to achieve a technical result, which consists in simplifying the design of the device, in reducing energy consumption and in increasing the duration of use of the accumulated cold. In addition, the proposed installation for cooling during its implementation allows you to achieve an additional technical result that was not in the prototype, namely: increasing the efficiency of heat transfer.

 The essence of the invention lies in the fact that in a cooling installation comprising a thermally insulated refrigerating chamber and a cold accumulator, including a sealed container filled with freezing liquid, means for cooling the liquid in the cold accumulator and means for transferring heat from the refrigerating chamber to the accumulator, including tubular coolants, one part of which is located in the capacity of the battery, and the other in the refrigerator, the means for cooling the liquid in the cold accumulator contains tubular holo car carriers, the lower part of which is located in the battery’s capacity, and the upper part is outside it for contact with natural atmospheric air, and each coolant contains a vertically extended metal casing with elastic walls filled with a liquid with a freezing temperature below the maximum possible negative temperature of atmospheric air, at than the battery capacity is insulated and located above the refrigerator. In addition, the coolants located in the refrigerating chamber are equipped with flow controllers for the liquid filling them, and the coolants located outside the battery capacity are equipped with a heat-insulated lid.

 The technical result is achieved as follows. Due to the fact that the installation includes devices that are simple in design: the cold accumulator is a sealed thermally insulated container filled with freezing liquid; thermally insulated refrigerator; the same type of coolant filled with non-freezing liquid all this allows you to unify the device as a whole and simplify its design. The implementation of the refrigerating chamber and the capacity of the cold accumulator insulated eliminates the heat exchange of their internal volumes with the outside air, ensures that they maintain the specified temperature and increases the duration of use of the accumulated cold. Due to the fact that the upper part of the coolant means for cooling the liquid in the capacity of the cold battery is located outside the battery capacity, the cold from the outside air is transferred to the battery capacity. At the same time, due to the fact that the coolants are filled with non-freezing liquid, the accumulation of cold outside air in them is ensured. The possibility of accumulation of cold taken from the outside air in the coolants of the liquid cooling means reduces the dependence of the temperature of the freezing liquid of the battery capacity on changes in the temperature of the outside air and increases the length of time the accumulated cold is used.

 At the same time, the use of liquid in coolants that freeze liquid in the battery capacity for transferring cold and not air (as in the prototype) increases the efficiency of heat transfer during cooling, since the coefficient of heat transfer from air to liquid through the metal wall of the coolant is lower than the coefficient of heat transfer from liquid to liquid through the metal wall of the coolant. Due to the fact that in the means for transferring heat from the refrigerating chamber to the cold accumulator, one part of the coolants is located in the battery capacity and the other in the refrigerating chamber, the cold accumulated by the non-freezing liquid is transferred to the refrigerating chamber.

 Since all coolants are filled with non-freezing liquid and contain vertically extended metal cases, convection of non-freezing liquid continuously occurs in them: cold liquid goes down and warmer one goes up, which ensures circulation and heat transfer. Thus, in the proposed installation for cooling, the circulation of the cold-transporting liquid and heat transfer are ensured by the natural circulation of the non-freezing fluid-convection. This allows you to abandon forced circulation, simplify the design of the device and reduce energy consumption. Moreover, the temperature inside the refrigerator is determined by its volume and the latent heat of fusion of the freezing liquid in the cold accumulator, which is selected for each specific case. The ability to select the freezing point of the freezing liquid that accumulates cold allows you to get low negative temperatures in the chamber, as well as adjust the length of time the accumulated cold is used.

 The elastic walls of vertically extended metal cases of coolants can increase the internal volume of the sealed capacity of the cold accumulator when the liquid filling it completely freezes by deforming the coolant bodies with it, which helps to increase the amount of accumulated cold and increases the length of time the accumulated cold is used.

 At the same time, the non-freezing liquid displaced from the cold carriers in the cold accumulator is transferred respectively to the external coolants and coolants of the refrigerating chamber. Due to the elasticity, the walls of their bodies bend outward and increase the internal volume of coolants. Since the heat transfer in the proposed installation is ensured by convection of an anti-freezing fluid in the coolants, an increase or decrease in the amount of non-freezing fluid in the coolants reduces or increases the speed of the convection process, and consequently, changes the heat transfer mode both between the refrigerator and the capacity of the cold accumulator, and between capacity of the accumulator of cold and outside air. As a result, heat transfer efficiency is increased.

 Due to the fact that during the use of the accumulated heat, the freezing liquid thaws out gradually, the coolants in the capacity of the cold accumulator also gradually restore their shape, and, consequently, the original volume, and at the same time, the liquid displaced from them, also gradually takes its former place, the amount of liquid in refrigerators of the refrigerating chamber decreases and their bodies gradually strive to restore their original shape. As a result of deformation of the coolant bodies, frozen ice is also gradually discarded from their surfaces. Thus, the device automatically provides seasonal discharge of ice from the coolant, as well as self-freezing of the refrigerator. In this case, the heat transfer mode changes, monitoring the temperature in the refrigerator.

 Dropping the frozen ice from the refrigeration media of the refrigeration chamber provides direct contact of the surfaces of the refrigeration cases with the air of the refrigeration chamber. This increases the efficiency of heat transfer, and, consequently, the duration of use of the accumulated cold. In addition, the regulation of the amount of non-freezing fluid in the refrigeration media of the refrigerator, depending on the required temperature, by the regulators of the flow of non-freezing fluid, also causes deformation of the coolant bodies, dropping of frozen ice from them and faster access to the required temperature regime.

 The heat-insulating cover on the external cooling media eliminates their heat exchange with natural atmospheric air in the warm season and maintains a stationary convection mode in the external cooling media and in the coolant accumulator connected coaxially to them.

 Thus, the invention in its implementation ensures the achievement of a technical result, which consists in simplifying the design and in reducing energy consumption, due to the possibility of unifying the installation and using the natural circulation of the cold-transporting liquid, namely, the phenomenon of convection of non-freezing liquid in the coolants of the installation; in the possibility of increasing the duration of the use of accumulated cold. In addition, in the proposed installation for cooling, an additional technical result is achieved, which was absent in the prototype: increasing the efficiency of heat transfer.

 In FIG. 1 shows an installation for cooling; in FIG. 2 - coolant, section AA in FIG. one.

 The cooling installation comprises a cold accumulator, including a sealed container 1, and a refrigerating chamber 2. The walls of the container 1 and the refrigerating chamber 2 are laid with a heat insulator 3. The tank 1 is filled with freezing liquid 4. In addition, the device contains means for cooling the liquid in the tank 1 of the cold accumulator and means for transferring heat from the refrigerator 2 to the cold accumulator. Means for cooling the liquid in the tank 1 of the cold accumulator contains tubular coolants 5, 6, 7, the lower part 7 of which is located in the tank 1 of the cold accumulator, and the upper part 5 is out of it for contact with natural atmospheric air. Each coolant 5, 6, 7 is filled with liquid 8 with a freezing temperature below the maximum possible negative temperature of natural atmospheric air. The means for transferring heat from the refrigerating chamber 2 to the battery contains tubular refrigerants 9, 10, 11, one part 9 of which is located in the battery container 1 and the other in the refrigerating chamber 2. Each refrigerant 9, 10, 11 is filled with liquid 8 with a freezing temperature below the maximum possible negative temperature of natural air.

 At the same time, each coolant contains a vertically extended metal casing 5, 7 and 9, 11, respectively, with elastic walls. In addition, the coolants 11 located in the refrigerating chamber 2 are equipped with regulators 12 for the flow of the liquid filling them, and the coolants 5 located outside the tank 1 of the cold accumulator are equipped with a heat-insulating cover that covers them in the warm season (not shown in Fig. 1).

 The regulators 12 of the flow of non-freezing fluid can be performed, for example, in the form of conventional valves, regulating the flow of fluid manually.

As the freezing liquid 4 can be used, for example, depending on the desired temperature regime of the refrigerating chamber 2, water, aqueous solutions, brines, chemicals with a latent heat of fusion from (+ 10 ^o ) to (-40 ^o ) C.

 The device operates as follows.

 In the cold period of time, the heat-insulating cover is removed from the external cooling media 5, thereby providing direct contact of the cooling media 5 with natural atmospheric air. In the refrigerating chamber 2 provide a temperature regime close to the temperature of natural atmospheric air. To do this, open transoms, and, if necessary, the front doors of chamber 2. In the coolant 5, the upper layers of non-freezing fluid 8 are cooled and, displacing the warm layers up, are lowered into the lower part of the coolant 5 and then through the coolant 6 to the lower part of the coolant 7. In turn displaced upward warm layers of antifreeze liquid 8, cooling in the coolants 5, also fall into the lower part of the coolants 7, displacing the warmer layers of antifreeze liquid 8, etc.

 Thus, in the coolants 5, 7, the process of convection of the liquid 8 takes place, which ensures its circulation and heat exchange in a natural way. As a result, the temperature of the freezing liquid 4 gradually decreases to its freezing temperature. The need for additional volume, taking into account the expansion of the liquid 4 during freezing, is compensated by the design of the coolants 7, 9, which, having elastic walls, reduce their volume when compressed by the frozen liquid 4, thereby increasing the free internal volume of the capacity 1 of the cold accumulator. In this case, the excess liquid 8 passes into the upper coolants 5 and coolants 11 of the refrigerating chamber 2. Their walls thus bend outward, increasing the internal volume of the coolant.

 Since in the cold season, the coolants 11 of the refrigerating chamber 2 are practically in contact with natural atmospheric air, the temperature of the liquid 8 in them is much faster equalized than in the coolants 9 of the chamber 1 communicated with them. This prevents the convection of the liquid 8 from the coolants 9 into the coolants 11. As a result , heat transfer between the liquid 4, accumulating external cold, and the internal volume of the refrigerating chamber 2 in the cold season is practically absent. When the liquid 4 is completely frozen, the convection process in the coolants 5, 6, 7 practically stops.

 With the onset of the warm season, the external coolants 5 are closed with a heat-insulating cover, which ensures the preservation of the steady-state convection regime of the fluid 8 in the coolants 5, 6, 7 and excludes its heat exchange with natural atmospheric air. The transoms and doors of the refrigerator compartment 2 are also closed, providing thermal insulation. In this case, the accumulated cold is transferred from the chamber 1 to the refrigerating chamber 2 by the coolants 9, 10, 11 also in a natural way by convection of the liquid 8 in them.

 Maintaining the required temperature in the refrigerating chamber 2 is carried out with the help of regulators 12 of the flow of non-freezing fluid in the coolants 11. To lower the temperature in the chamber 2, increase the flow of non-freezing fluid through the coolants 11, and to increase the temperature, reduce it.

Claims (2)

 1. Installation for cooling, comprising an insulated refrigerating chamber and a cold accumulator, including a sealed container filled with freezing liquid, means for cooling the liquid in the cold accumulator, and means for transferring heat from the refrigerating chamber to the battery, including tubular coolants, one part of which is located in the container battery, and the other in the refrigerator, characterized in that the means for cooling the liquid in the cold accumulator contains tubular coolants, the lower part which is located in the capacity of the battery, and the upper part is outside for contact with natural atmospheric air, each coolant contains a vertically extended metal casing with elastic walls filled with liquid with a freezing temperature below the maximum possible negative temperature of natural atmospheric air, and the battery capacity is made thermally insulated and located above the refrigerator.  2. Installation for cooling according to claim 1, characterized in that the coolants located in the refrigerating chamber are equipped with flow regulators of the liquid filling them, and the coolants located outside the battery capacity are equipped with a heat-insulating cover.

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