RU144263U1 - THERMOELECTRIC UNIT - Google Patents

Abstract

1. Thermoelectric unit containing thermoelectric modules, each of which is made of air and water heat exchangers, with thermoelectric coolers located between them, a cooling air circulation fan, characterized in that said unit is mounted on a box-shaped frame inside which air ducts are formed, at least with at least one fan and at least two thermoelectric modules, radiators of air heat exchangers, which are installed on the outer surface of the frame laid inside the ducts. 2. Thermoelectric unit according to claim 1, characterized in that each fan is mounted on a confuser, which is mounted on a frame. 3. The thermoelectric unit according to claim 2, characterized in that the confusers are additionally connected by a plate on which a sealed junction box is installed, into which cables from each thermoelectric module, a temperature controller sensor, external electrical connections, fans are connected through stuffing box inputs. Thermoelectric unit according to claim 1, characterized in that the thermoelectric modules are connected to each other by water pipelines in parallel-serial. Thermoelectric unit according to claim 1, characterized in that at the bottom of the frame is a casing made in the form of a funnel. 6. Thermoelectric unit according to claim 1, characterized in that the thermoelectric modules are mounted on a rubber gasket made of frost-resistant rubber. A thermoelectric unit according to claim 1, characterized in that insulating tubes are installed between the thermoelectric modules and the frame. Thermoelectric �

Description

Technical field

The utility model relates to refrigeration equipment, namely, thermoelectric refrigeration units and can be used, for example, for cooling air in food pantries on ships in harsh operating conditions, as well as in air conditioning devices.

The principle of operation of a thermoelectric unit (hereinafter thermoblock), consisting of thermoelectric modules (hereinafter thermomodules), is based on the Peltier effect. When a DC voltage is applied to the unit at the junctions of thermoelectric modules (coolers), a temperature difference occurs, which causes heat transfer from a low temperature level (air pantries), to a higher (cooling water).

The heat from the volume of the provisions storeroom is absorbed by air heat exchangers and, together with the heat equivalent to the power consumption of thermoelectric coolers, is transferred to water heat exchangers, where it is cooled by running water.

One of the urgent problems today is ensuring the efficiency of air cooling in rooms of limited volume, for example, food pantries, on ships operating in harsh operating conditions.

State of the art

Known refrigeration thermoelectric unit RU 2092753 F25B 21/02, published 10.10.1997. The unit contains two or more heat coolers, on the hot and cold junctions of which radiators are installed. The space between the radiators and the cavity between the hot and cold junctions are filled with heat-insulating moisture-proof material, the hot junctions radiator is made in the form of autonomous sections mounted on only one thermoelectric module, while the radiator and the fan for blowing it are placed in a casing having the shape of a diffuser with narrowing to the side radiator. The air inlet and outlet openings are made on opposite end sides of the casing.

Known thermoelectric climate control system for limited air volume RU 2482396, F25B 21/02, published 01/20/2013. The system comprises a control unit and a thermoelectric unit comprising a base with a thermoelectric battery installed between an external heat sink-heat exchanger pressed against each other, pressed against a plate of a thermoelectric battery and an internal heat sink-heat exchanger, pressed against its other plate. The radiators are equipped with DC fans.

Known thermoelectric refrigeration unit RU 2267720, F25B 21/02, published 10.01.2006. It contains a cooled chamber and an intermediate circulation coolant circuit, including an external heat exchanger with a fan and a thermoelectric cooling unit located in the cooled chamber with thermoelectric cooling modules, including heat-absorbing and heat-generating junctions. A heat sink pipe made in the form of a glass is installed in the wall of the cooled chamber. An exhaust pipe is installed inside the heat sink pipe. Thermoelectric cooling modules with heat-generating junctions are installed on the outer surface of the heat-sink pipe, and heat-absorbing junctions are placed in the cooled chamber. The unit can be used in home refrigerators. This technical decision was made as a prototype.

The disadvantages of the known solutions include the low maintainability of the installation, since if a malfunction occurs in a thermoelectric refrigeration unit, the entire assembly must be dismantled.

It is known that the reliability of a thermoelectric unit with thermoelectric modules is determined by the reliability and efficiency of its main components.

To ensure continuous operation and eliminate the reduction in the cooling capacity of the fuser, conditions must be provided for the rapid replacement of failed nodes and elements (preferably without completely disassembling the fuser).

This task becomes especially urgent when using thermoblocks in special harsh operating conditions, for example, on ships, when contingencies may arise, in which prompt replacement of faulty components and elements is required.

The problem, which the utility model is aimed at, is to create a new reliable design of the fuser operating in harsh operating conditions on ships.

The technical result of the utility model is to increase the maintainability of the fuser.

Utility Model Disclosure

The problem is solved as follows

The thermoelectric unit contains thermoelectric modules, each of which is made of air and water heat exchangers, with thermoelectric coolers located between them, a cooling air circulation fan, and characterized in that the said unit is mounted on a box-shaped frame inside which ducts are formed, at least with with one fan, and on the outer surface of the frame, at least two thermoelectric modules are installed, the radiators of air heat exchangers of which are located veins inside the ducts. Each fan is mounted on a confuser, which is fixed to the frame, and the confusers are additionally connected by a plate. A sealed junction box is installed on the plate, into which cables from each thermoelectric module, a temperature controller sensor, external electrical connections, fans are passed through stuffing box inputs. In addition, thermoelectric modules are connected to each other by water pipelines in parallel-series.

In addition, at the bottom of the frame is a casing made in the form of a funnel for collecting and removing condensate

In addition, thermoelectric modules are mounted on a rubber gasket made of frost-resistant rubber, while thermoelectric modules and a frame are equipped with insulating tubes.

In addition, handles for carrying and mounting are provided on the frame. In addition, the sensor of the room air temperature controller is installed on the bracket at the bottom of the housing when air enters the ducts.

Utility Model Implementation

The inventive utility model is illustrated by drawings, Figure 1 shows a front view of the fuser, figure 2 is a side view, figure 3 is a mounting unit of the thermoelectric module to the frame.

The thermal block consists of a welded frame 1, with thermoelectric modules 2 mounted on it.

Depending on the cooling capacity of the fuser, the number of thermoelectric modules included in it can be 2, 4 or more, and is determined by the capabilities of the fans used and the mass of the unit. With an increase in the number of thermoelectric modules, the requirements for electric fans increase, which should provide the necessary air flow in conditions of increasing aerodynamic drag. In this case, the power and noise of the fans inevitably increase. In addition, each pair of added thermoelectric modules increases the weight of the fuser by about 25-30 kg, which must be taken into account when using the fuser in confined spaces.

Figure 1 shows the design with four thermoelectric modules, each of which consists of air 3 and water 4 heat exchangers with thermoelectric coolers installed between them in thermal contact.

Thermoelectric modules are attached to the welded, box-shaped frame, 1 by means of threaded rods 5 through a rubber gasket 6. Electrical insulating sleeves 7 are installed between the studs and the frame, and the studs are tightened with nuts made of electrical insulating material, for example, caprolon. Such a mount provides electrical insulation of the thermoelectric module from the frame and increases the reliability of electrical insulation of power circuits during operation of the fuser in conditions of high humidity. When installing thermoelectric barrels, the cooled air radiators are located inside the box ducts 8, which are elements of the frame 1. Thermoelectric modules are connected to each other by electric cables and flexible hoses for supplying and discharging cooling water. This design creates several advantages:

- excluded the transfer of mechanical deformation between individual thermoelectric modules, both during assembly and during operation of the fuser;

- reduced the effect of thermoelectric modules on each other when the deviations of the electrical, thermal or hydraulic parameters of one of them;

- the relative simplicity of repair of the fuser is ensured, since it boils down to disconnecting the faulty thermoelectric module from electric circuits and the hydraulic path, without completely disassembling the thermoelectric module or thermoblock and then replacing it with a working block;

- redundancy of control and protection sensors is provided, since sensors are available in each thermoelectric module, despite the fact that there is no need to use all of them.

Two welded confusers 9 with two fans 10 and a welded casing 11 are attached to the welded frame 1. Each fan provides air pumping through its box duct, in which the radiators of two thermoelectric modules are located. This design provides a uniform distribution of cooled air in the conditions of increasing aerodynamic drag of radiators due to freezing of the ribs. In addition, by streamlining the air flow, the noise level is reduced.

The fans 10 are attached to the confusers 9 with knurled nuts and connected to the electrical circuit of the thermoelectric unit by means of connectors, which makes it possible to quickly replace a faulty fan in case of failure.

The purpose of the welded casing 11 is the collection and removal of the condensate generated during the thawing process outside the thermal block. The casing shape is developed based on the requirements for completeness of condensate collection in roll and roll conditions on ships, subject to minimal aerodynamic resistance to the flow of cooled air.

Handles 12 are provided for carrying and facilitating installation on frame 1

The material of all structural elements is aluminum alloy. At the level of the fan flanges, the confusers are additionally fastened with a plate 13 on which the junction box 14 is mounted to increase the overall stiffness.

The frame of the frame 1 has a flange with holes for attaching the fuser to the wall of the refrigerator.

On the bracket 15 are fixed two plug sockets 16 for external electrical connections of the fuser. One connector contains a chain of control and protection sensors, and the second is used to connect thermoelectric modules and fans. This separation is designed to reduce the level of electrical noise in the sensor circuits and simplifies the choice of cable type for external connections.

The sensor of the temperature controller 17 of the air in the pantry is mounted on the bracket when the air enters the fuser. This arrangement of the sensor allows, in comparison with the arrangement directly on the surface of the radiator, to more accurately monitor the temperature of the air in the cooled volume and does not put forward additional requirements for the cooled volume, since it does not require the installation of the sensor directly in the volume.

The connection cables are protected from mechanical damage and contact with the consumer by a strip 18. All connections between thermoelectric modules, connectors for external connections, fans and sensors are made using a sealed junction box 14, into which cables from each thermoelectric module, a temperature controller sensor are connected through gland entries 17 and external electrical connectors. The box is hermetically sealed with a lid with connectors for connecting fans installed on it.

Cooling water enters the fuser through flexible rubber hoses 19, due to which the expansion of the possibilities of mutual arrangement of the fuser and the places of external connections of cooling water is provided.

Using tees 20, a crosspiece 21 and rubber pipes 22, thermoelectric modules are connected in parallel-series through the water, which allows, if necessary, to drain the water from the heat exchangers.

To drain the water from the fuser and release the air when filling it with water, threaded plugs are designed, respectively 23 and 24, located on the tees 20.

The sealing of rubber elements of pipelines with metal is achieved by means of steel clamps 25 with screw clamping, which simplifies the necessary disconnections and connections in the hydraulic path of the fuser.

In order to prevent moisture condensation on the open surface of the fuser frame 1, thermoelectric modules are mounted on a rubber gasket made of frost-resistant rubber

When the fuser is switched on, voltage is supplied to the thermal modules in polarity, at which the air heat exchangers are cooled and the heat is given to running water. The air of the cooled room with the help of fans is driven through the intercostal gaps of the air heat exchangers and cooled.

In defrosting mode, voltage is supplied to thermoelectric modules in reverse polarity. In this case, air heat exchangers are heated to a temperature at which the snow "coat" on the ribbed surface melts and the ribs are cleaned. Meltwater is removed from the fuser. At the end of defrosting, the fuser is switched back into cooling mode.

Claims (9)

1. Thermoelectric unit containing thermoelectric modules, each of which is made of air and water heat exchangers, with thermoelectric coolers located between them, a cooling air circulation fan, characterized in that said unit is mounted on a box-shaped frame inside which air ducts are formed, at least with at least one fan and at least two thermoelectric modules, radiators of air heat exchangers, which are installed on the outer surface of the frame laid inside the ducts. 2. The thermoelectric unit according to claim 1, characterized in that each fan is mounted on a confuser, which is mounted on a frame. 3. The thermoelectric unit according to claim 2, characterized in that the confusers are additionally connected by a plate on which a sealed junction box is installed, into which cables from each thermoelectric module, a temperature controller sensor, external electrical connections, fans are connected through stuffing box inputs. 4. The thermoelectric unit according to claim 1, characterized in that the thermoelectric modules are connected to each other by water pipelines in parallel-series. 5. The thermoelectric unit according to claim 1, characterized in that at the bottom of the frame is a casing made in the form of a funnel. 6. The thermoelectric unit according to claim 1, characterized in that the thermoelectric modules are mounted on a rubber gasket made of frost-resistant rubber. 7. The thermoelectric unit according to claim 1, characterized in that insulating tubes are installed between the thermoelectric modules and the frame. 8. The thermoelectric unit according to claim 1, characterized in that the handles for carrying and mounting are mounted on the frame. 9. The thermoelectric unit according to claim 3, characterized in that the sensor of the room air temperature controller is mounted on the bracket at the bottom of the housing when the air enters the ducts.