RU183345U1 - DEVICE FOR TRANSFORMING THERMAL ENERGY OF A TRANSFORMER TO ELECTRIC ENERGY - Google Patents

Abstract

The utility model relates to electrical engineering and energy, can be used to generate electrical energy using heat generated during operation of the transformer. Effect: increase the efficiency of the transformer. Essence: a device for converting thermal energy of a transformer into electrical energy contains thermoelectric generators made in the form of TEG plates based on semiconductor thermoelectric materials that are coated with a thermal interface and mounted on a mounting plate. The electrical leads of thermoelectric generators in the mounting plate are connected to a single electrical circuit. Current collector electrodes are mounted in various sections of this electric circuit. 7 c.p. f-ly, 6 ill.

Description

The utility model relates to electrical engineering and energy, can be used to generate electrical energy using the heat generated during operation of the transformer. [H01L 35/00]

The prior art describes a method of using transformer heat implemented in a DEVICE FOR USING TRANSFORMER HEAT [RU 158960 U1, publ.: 01.20.2016], in which primary coolant is pumped through the transformer tank and the heating side of the heat exchanger along the circuit, and through the circuit through the heated side of the heat exchanger and the evaporator of the heat pump pump the coolant of the second circuit, transfer heat from the heating side of the heat exchanger to the heated side, heat the coolant of the second circuit, the circulation through the heat pump evaporator, while in the internal pipeline circuit of the heat pump, the secondary coolant at the appropriate pressure is brought to a boil and fed to the compressor, compressed by it, heated by compression and pushed into the condenser, in which the heating circuit water is cooled to a liquid state, and through a throttle that provides a pressure differential, it is fed to the evaporator, where it is again transferred to the gas phase, heating to a boil by the coolant circuit. The disadvantage of the analogue is the low efficiency of the transformer, due to the need to use additional energy sources for the operation of the pumps for supplying coolants of the first and second circuits.

The closest in technical essence is a DEVICE FOR COOLING an OIL TRANSFORMER [RU 172184 U1, publ.: 06/30/2017], containing a metal tank with a lid and a bottom, made expanded in the lower part with the formation along the perimeter of the tank above the bottom of the horizontal platform with holes in which heat exchangers made in the form of vertical heat pipes with heating and cooling zones are uniformly fixed around the perimeter of the tank, characterized in that in the cooling zone around the perimeter of the heat pipes are square or rectangular section On the other hand, thermoelectric converters are installed that are attached to the heat pipes by the cold side, and heat-removing fins are installed on the heated side of thermoelectric converters to remove heat into the environment.

The main technical problem of the prototype is the use of heat pipes to transfer heat to the cooling zone to thermoelectric converters, which causes additional heat loss from radiation by the heated surfaces of the heat pipes to the environment from areas where thermoelectric heaters are not installed, which leads to a low efficiency of the transformer.

The objective of the utility model is to eliminate the disadvantages of the prototype.

The technical result of the utility model is to increase the efficiency of the transformer.

The specified technical result is achieved due to the fact that the device converts the thermal energy of the transformer into electrical energy containing thermoelectric generators, characterized in that the thermoelectric generators are made in the form of TEG plates based on semiconductor thermoelectric materials that are coated with a thermal interface and mounted on a mounting plate so that the electrical leads of thermoelectric generators in the mounting plate are connected into a single electrical circuit, while different nye portions of this electric circuit the current collecting electrodes are mounted.

In particular, on the opposite side of the mounting plate of the relative thermoelectric generators, heat-removing fins are made. In particular, a voltage converter is connected to the collector electrodes of the mounting plate, to the output of which a consumer of electrical energy is connected.

In particular, a temperature controller is connected to the control inputs of the transformer and to the collector electrodes of the mounting plate, which is configured to maintain the required temperature conditions of the transformer and thermoelectric generators.

In particular, the mounting plate is made of a material with high thermal conductivity.

In particular, the voltage converter is designed as a DC / AC converter. In particular, it contains springs made with the possibility of fixing between the mounting plate and the adjacent radiator.

In particular, it contains springs made with the possibility of fixing between two mounting plates adjacent to adjacent transformer cooling radiators.

A brief description of the drawings.

In FIG. 1 shows a general view of a device for converting thermal energy of a transformer into electrical energy.

In FIG. 2 shows a general view of a device for converting the thermal energy of a transformer into electrical energy with heat sink fins on a mounting plate.

In FIG. Figure 3 shows a side view of the mounting plate mounting on a plate radiator of a transformer using holding brackets.

In FIG. 4 shows a side view of the mounting plate mounting on the transformer plate radiator using springs.

In FIG. 5 shows a side view of the mounting of a pair of mounting plates with thermoelectric generators between the plate radiators of the transformer using springs.

In FIG. 6 schematically shows a block system of a device for converting thermal energy of a transformer into electrical energy.

The figures indicate: 1 - thermoelectric generators, 2 - mounting plate, 3 - heat sink fins, 4 - plate radiators, 5 - staples, 6 - springs, 7 - transformer, 8 - voltage converter, 9 - electric energy consumer, 10 - controller .

Implementation of a utility model.

A device for converting thermal energy of a transformer into electrical energy contains thermoelectric generators 1 (see Fig. 1) made in the form of TEG plates based on semiconductor thermoelectric materials that are mounted on a mounting plate 2. In the mounting plate 2, the electrical terminals of the thermoelectric generators 1 are connected to an electric circuit, while collector electrodes are mounted in different sections of the electric circuit, made with the possibility of choosing the number of thermoelectric nerator 1, which make up the electrical network between the collector electrodes.

In one embodiment of the claimed solution, on the opposite side of the mounting plate 2 of the relative thermoelectric generators 1, heat-removing fins 3 can be made (see Fig. 2).

In working condition, the mounting plate 2 with thermoelectric generators 1 is located between the plate radiators 4 of the transformer 7, while according to one embodiment of the mounting, the mounting plate 2 is held on the plate radiator 4 due to the elastic force of the compression brackets 5 (see Fig. 3). According to another embodiment of the fastening, the mounting plate 2 is held on the plate radiator 4 due to the elastic force of the springs 6 (see Fig. 4 and Fig. 5) located on the side of the mounting plate 2, the opposite side of the thermoelectric generators 1.

A voltage converter is connected to the collector electrodes of the plate 2, to the output of which a consumer of electric energy 9 is connected. A temperature controller 10 is connected to the controlled inputs of the transformer 7 and to the collector electrodes of the plate 2.

A device for converting thermal energy of a transformer into electrical energy is collected and mounted as follows.

A thermal interface is applied to the surface of the thermoelectric generators 1 (not shown in the figures), then they are mounted on the mounting plate 2, while the electrical terminals of the thermoelectric generators 1 are mated with the conductors of the electrical circuit of the mounting plate 2. After that, the mounting plate 2 with thermoelectric generators 2 is mounted on the plate the radiator 4 of the transformer 7 so that the thermoelectric generators 1 with the thermal interface applied to them fit snugly against the plate radiator 4. Then to the collector electrodes of the mounting plate 2 are connected in series with the voltage converter 8 and the consumer 9, while the controller 10 is connected to the control inputs of the transformer 7 and the collector electrodes of the plate 2.

The holding of the mounting plate 2 with thermoelectric generators 1 according to the first embodiment is ensured by the brackets 5 mounted around the perimeter of the mounting plate 2 and the plate radiator (see Fig. 3). According to the second embodiment, the holding of the mounting plate 2 with thermoelectric generators 1 on the plate radiator 4 is ensured by the elastic force of the springs 6, while the springs 6 can be placed between the mounting plate 2 and the adjacent radiator 4 (see Fig. 4) or between 2 mounting plates 2 adjacent to adjacent radiators 4 (see. Fig. 5).

A device for converting thermal energy of a transformer into electrical energy is used as follows.

After turning on the transformer 7, heat from the plate radiator 4 is transmitted through the thermal interface to the surface of the thermoelectric generators 1, in each of which a volumetric thermo-emf is created between their terminals. To increase the EMF, the opposite side of the mounting plate 2 is cooled, while cooling, depending on the heat load, is performed by increasing the area of the surface to be cooled using heat-removing fins 3 or using a forced cooling system (not shown in the figures). Under the influence of EMF, an electric current occurs inside the semiconductor material of thermoelectric generators 1, and a potential difference arises between the terminals, which is removed from the collector electrodes. Depending on the number of thermoelectric generators 1 and the method of their connection in the circuit between the current collector contacts, the value of the output voltage and current are varied. The voltage from the current-collecting contacts is fed to the input of the voltage converter 8 (see Fig. 6), in which the DC voltage is converted to AC voltage, and / or the voltage value and transmitted from the output of the voltage converter 8 to consumer 9. The consumer can be like the system itself cooling transformer and autotransformer, as well as third-party consumers involved in the process of electrical substations and stations. To maintain the temperature conditions of the transformer 7 and thermoelectric generators 1, the controller 10 monitors the oil temperature, the temperature of the cooling radiator 4 and the temperature of the cooled surfaces of the thermoelectric generators 1 and, if necessary, displays the device in emergency mode and thermal shunting to prevent overheating. The claimed technical result is achieved through the use of thermoelectric generators 1, coated with a thermal interface and tightly adjacent to the plate radiator 4 of the transformer 7.

Thus, the use of the claimed technical solution allows you to effectively convert the heat generated by the transformer into electrical energy and thereby increase the efficiency of the transformer, while the use of a set of collector electrodes allows you to adjust the cooling ability of thermoelectric generators 1 and change the efficiency.

Claims (8)

1. A device for converting the thermal energy of a transformer into electrical energy containing thermoelectric generators, characterized in that the thermoelectric generators are made in the form of TEG plates based on semiconductor thermoelectric materials that are coated with a thermal interface and mounted on a mounting plate so that the electrical terminals of thermoelectric generators are the mounting plate is connected in a single electrical circuit, while in various parts of the electrical circuit mounted current removable electrodes. 2. The device according to p. 1, characterized in that on the opposite side of the mounting plate of the relative thermoelectric generators, heat-conducting fins are made. 3. The device according to claim 1, characterized in that a voltage converter is connected to the collector electrodes of the mounting plate, to the output of which a consumer of electrical energy is connected. 4. The device according to claim 1, characterized in that a temperature controller is connected to the control inputs of the transformer and to the collector electrodes of the mounting plate, which is configured to maintain the required temperature conditions of the transformer and thermoelectric generators. 5. The device according to claim 1, characterized in that the mounting plate is made of a material with high thermal conductivity. 6. The device according to claim 1, characterized in that the voltage converter is made in the form of a DC / AC converter. 7. The device according to p. 1, characterized in that it contains springs made with the possibility of fixation between the mounting plate and the adjacent radiator. 8. The device according to p. 1, characterized in that it contains springs made with the possibility of fixation between two mounting plates adjacent to adjacent transformer cooling radiators.

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