RU41354U1 - THERMOELECTRIC LIQUID COOLING SYSTEM - Google Patents

Abstract

The invention relates to refrigeration, and in particular, to systems for cooling drinks, and can be used in enterprises selling drinks: beer, water, juices, milk. The invention relates to environmentally friendly devices. The thermoelectric cooling system contains a thermally insulated tank, thermopiles with thermo modules mounted on its walls, a heat release unit with radiators and fans. The original design of the heat release unit allowed to improve technical and operational characteristics, increase fire safety.

Description

The invention relates to environmentally friendly devices intended for cooling to the required temperature of a liquid in a thermally insulated volume. The invention relates to refrigeration and can be used in the food industry, in particular, at enterprises selling drinks, such as, for example, beer, juices, milk and other liquid products.

Known cooling systems using thermoelectric devices for cooling water, which are usually called elements based on the Peltier effect.

Peltier elements in such use cases are usually applied in the form of flat elements with a constant voltage applied between two opposite active surfaces of the element. Direct current causes heat transfer from one active surface of the element to another. In this case, one side of the element is cooled, and the other is heated. Active surfaces are usually made in the form of heat-conducting plates, for example, of ceramics, and the thermocouples located between them are made in the form of an array of electrically connected p-and n-type thermopiles made of materials with the desired thermoelectric characteristics, for example, bismuth telluride. In general, this design is called a thermal module. Each thermal module has current leads. When providing a thermal connection of the cold active surface of the thermal modules of the thermopile with the inner part of the isolated volume, the cooling of the liquid in its internal volume occurs.

The reliability of obtaining the necessary cooling of the liquid depends on the design that provides certain necessary conditions for the operation of thermal modules in a thermal battery, which are as follows. To ensure trouble-free and efficient operation of each of the thermal modules of the thermopile installed on the walls of a thermally insulated tank, it is necessary to ensure the simultaneous occurrence of two processes: - intensive removal of cold from their cold surfaces and the same intensity of heat removal from hot surfaces of the thermal modules.

At present, a rather urgent task is to create a thermoelectric liquid cooling system that is simple in design, reliable, trouble-free, and efficient in obtaining the necessary liquid cooling with a volume of, for example, about 2 liters. Moreover, the system design should provide intensive heat removal from a hot surface

thermal modules with the help of trouble-free and simple in design heat block.

Known thermoelectric systems for cooling liquids in tanks, in which the problem of heat removal from the hot surfaces of thermal modules is structurally solved. However, as a rule, such designs are quite complex, which increases the likelihood of system crashes as a whole.

Thus, a known beverage cooling system [1], comprising a block of thermoelectric batteries having hot and cold circuits for a coolant and a heat rejection unit including a circulation pump, a radiator with a fan, a gas separation device. This device is quite complicated, it has many connecting pipelines that increase the accident rate of the system. Also, the probability of a design accident increases due to the use of water as a coolant, a leakage of two droplets the size of which can cause a short circuit, as well as unacceptable overheating of thermal modules, which cause a fire of insulation and other flammable materials. A small assembly error or a crack in the pipeline can also quickly lead to an emergency, which may result, for example, in a fire.

Known simpler in design thermoelectric system for cooling the water supply [2], consisting of a tank with an inlet and a drain valve, thermoelectric modules with flow heat sinks and a water filter. Flowing heat sinks are made in the form of metal plates, inside of which are made Z-shaped channels for the passage of water through hoses connecting the upper filter with water, channels and the lower tank. Water flows through the channels of flowing heat sinks by gravity, without the use of pumps.

This thermoelectric water supply cooling system is not sufficiently reliable in operation, complex in design and prone to emergency situations.

The closest in technical essence to the claimed object is a thermoelectric cooling system of bottled water [3]. This system has a chilled water storage tank with an inlet and a drain cock. The thermoelectric module is located under the bottom wall of the tank. One side of the thermoelectric module is cooled, thereby cooling the water tank, and on the other, heated side there is a flow heat sink through which water is circulated through the pipeline using a pump. The drive shaft of the pump is pulled out of the motor in the opposite direction from the tank, and carries a small fan to create a convective air flow that helps cool the motor. Further, this air flow is directed to the heat exchanger, further contributing to the removal of heat from the closed loop.

The design of this system is quite complex and is not emergency safe. This system has no reserves to increase cooling capacity by increasing the cooling intensity of the hot side of the thermal module. Unreliable and complex is the design of flow (water) heat sink.

The problem to which this technical solution is aimed is to create a thermoelectric liquid cooling system that differs from the known ones by a sufficiently high degree of trouble-free, effective in obtaining the required liquid cooling temperature due to the efficient, simple in design heat-transfer unit, providing an intensive, precisely oriented direction cooling air flow, which prevents overheating of the thermal modules in continuous cooling mode. In this case, the achievement of the following technical and economic results should be ensured:

- improvement of technical and operational characteristics;

- low inertia;

- high reliability;

- lack of noise;

- the possibility of application on moving objects;

- the possibility of operation in a wide range of climatic conditions;

- fire safety.

A thermoelectric liquid cooling system is proposed, containing a vertical thermally insulated tank located in the housing with inlet and outlet fittings for supplying and discharging liquid and thermo-batteries with thermo-modules fixed on its walls, each of which has cold and hot active surfaces, a heat-release unit from hot surfaces of thermo-modules with radiators and fans.

Achievement of the indicated technical results is ensured due to the fact that the thermoelectric liquid cooling system is equipped with a reflective spreading device installed in the center of the heat sink between fans and radiators, made in the form of an irregular polyhedron with smaller and larger bases and four side faces, of which two opposite faces are made in the form orthogonal trapezoid, and the other two faces are made in the form of oblique trapezoid and are located at an acute angle to a larger base, Nome on the outer surface of the bottom of said vessel, and the smaller base of the polyhedron is arranged in a plane at which the two sides of the fan housing installed such that each of them jointly with the inclined face of the polyhedron rastekatelya forms a channel of the distributed coolant flow.

The claimed technical solution may be recognized as meeting the requirements of novelty, since no analogue characterized by

features identical to all the essential features of the invention.

The claimed technical solution meets the requirement of industrial applicability, since it is manufactured and used (Advert. List attached).

The essence of the claimed device is illustrated by the following drawings:

- figure 1 is a General view of a thermoelectric liquid cooling system (axonometry);

- figure 2 is the same, (section AA);

- figure 3 - reflective spreading (axonometry);

- figure 4 - thermopile with thermal modules;

- figure 5 - thermal module (axonometry).

The thermoelectric liquid cooling system 1 contains (see FIGS. 1, 2) a vertically insulated (pos. 3) tank 4 located in the housing 2 with an inlet 5 and an outlet 6 fittings, respectively, for supplying liquid, for example, water from a water supply system (not shown) and draining the liquid into the consumer's container. On two opposite side walls of the tank 4 are fixed thermal batteries 7 with thermal modules 8 (see Fig.4, 5), each of which has a cold 9 and 10 hot active surfaces. Cold active surfaces of 9 thermal modules are in contact with the walls of the tank, cool them, thereby cooling the liquid. To remove heat from the air from the hot active surfaces 10 of the thermal modules 8, a heat release unit 11 with radiators 12 and fans 13 is installed. To intensify the process of removing warm air, the thermoelectric system 1 is equipped with a reflective spreading device 14. The reflecting spreading device 14 (2, 3) is made in the form of an incorrect a polyhedron with a smaller 15 and a large 16 bases and four side faces, of which two opposite faces 17 and 18 are made in the form of orthogonal trapezoids, and the other two faces 19 and 20 are made in the form of inclined trapezoids and located at an acute angle, for example at 45 °, to the larger base 16 (figure 3).

Reflecting spreading device 14 is installed (Fig. 2) in the center of the heat-release unit 11 between the fans and radiators as follows: the larger base 16 of the spreading device is mounted on the outer surface of the bottom of the tank 4, to the smaller base 15 of the spreading device is mounted 2, on which two sides are installed fan so that each of the fans together with the face of the inclined trapezoid of the spreading device forms the channel 19 of the distributed flow of coolant (for example, air). There are two such channels 19 in this thermoelectric system 1. In each of these channels 19, there is a change in the direction of the air jets and an increase in the speed of the formed air stream directed precisely at the radiator, due to the presence of the reflecting spreader 14 and channel 19. Thus, an intense air stream is created, which increases the cooling efficiency of the hot 10 surfaces of the thermal modules 8.

Thermoelectric cooling system 1 operates as follows (see Fig.1-5). The principle of operation of the refrigerator is based on the use of the Peltier effect, when when passing direct current through the contacts of two dissimilar substances (metals, semiconductors) that make up thermomodule 8, cooling occurs on one of the contacts (heat absorption), and heat is released on the other. Initially, the reservoir 1 is filled with liquid, for example, water. By switching on the “Network” toggle switch (not shown in FIG.), Voltage is applied to the thermomodules 8 and fans 13. From this moment, the process of cooling the cold 9 surfaces of the thermomodules 8 of the thermopile 7 begins, cooling the inside of the tank 4 and the liquid inside it. Simultaneously with the cooling process, a process of heat generation takes place on the hot surfaces 10 of the thermal modules 8 of the thermal batteries 7, which is transmitted to the heat sink 12 of the heat sink 11. Each heat sink 12 is blown by an intensified flow of cooling air formed in the channel 19 by means of a reflecting raster 14 to which air is supplied by the fan 13 providing air supply to the radiator fins and heat removal to the external environment. The formation of an intense, changed in speed and direction of the cooling air flow in the heat discharge unit is as follows. When the air stream is supplied by the fan 13 to the channel 19, it strikes the inclined face 15 of the polyhedron of the spreading device 14, changes the direction of the air jets [orienting them towards the radiator fins] and increases the air flow rate, that is, provides a uniform intensive oriented directional flow of the cooling air, which, quickly enveloping the fins of the radiator, take heat and under the influence of a fan at a high speed transfer a warm stream of air into the external environment.

Thus, due to the fact that in the claimed design, the cooling process of the hot active surfaces of the thermal modules is intensified, the cooling rate of the liquid of the thermoelectric system 1 is increased.

Upon reaching a predetermined cooling temperature, monitored by sensors (not shown in Fig.), The cooled liquid (for example, drinking water) through the outlet nipple 6 (using a hose) is supplied to the consumer's container or bottled. Then the cooling process is repeated.

The proposed thermoelectric liquid cooling system differs from the well-known simple, reliable and trouble-free design, which provides intensive heat removal from the hot active surfaces of the thermocouples using a trouble-free and simple in design heat transfer unit and provides quick and efficient cooling of the liquid in the tank. At the same time, the following technical and economic results were achieved:

- improved technical and operational characteristics;

- the compact design is ensured, maintainability and reliability during operation are increased;

- increased effective use of an environmentally friendly source of cold;

- increased safety and trouble-free use, especially on moving objects;

- provided the possibility of operation in a wide range of climatic conditions;

- increased fire safety.

SOURCES OF INFORMATION USED:

1. Beverage cooling system.

RF patent No. 2154782, M. cl. F 25 D _^21/02, 08.20.2000.

2. Thermoelectric cooling system for water supply.

RF patent No. 2190167, M. cl. The 25 F _^21/02, 30.06.2000.

3. Thermoelectric cooling system for bottled water.

Claims (1)

A thermoelectric liquid cooling system containing a vertical thermally insulated tank located in the housing with inlet and outlet fittings for supplying and discharging liquid and thermo batteries with thermo modules mounted on its walls, each of which has cold and hot active surfaces, a thermal discharge unit from hot surfaces of thermo modules with radiators and fans, characterized in that it is provided with a reflective spreading device installed in the center of the heat-discharge unit between the fans and radiators, made shaped in the form of an irregular polyhedron with smaller and larger bases and four side faces, of which two opposite faces are made oblique at an acute angle to a larger base fixed to the outer surface of the bottom of the said tank so that the said inclined faces are placed under the tank and the smaller base of the polyhedron is located in a plane under which fans are installed on both sides of the casing so that each of them together with each inclined face facing the bottom of the tank is mentioned of polyhedron forms a channel of the distributed coolant flow.