RU153776U1 - THERMOELECTRIC GENERATOR WITH INCREASED EFFICIENCY - Google Patents

Abstract

The proposed utility model relates to the field of energy, namely to thermoelectric instrumentation. Thermoelectric generator, contains a heat receiver, structural fasteners that are in thermal conjugation with each other and heat removal means. The internal cavity of the heat removal means contains a liquid coolant, boiling point, which is lower than the boiling point of water under normal conditions. The internal cavity of the heat removal means is additionally made with a degree of vacuum, ensuring the creation of an artificial lowering of the boiling point of the liquid coolant. Provides increased output power of the generator. 2 s.p. f-ly, 2 ill.

Description

Technical field

The proposed utility model relates to the field of thermoelectric instrumentation as a source of direct conversion of thermal energy into electrical energy, based on the Seebeck effect, namely to thermoelectric direct current sources of increased power, designed for autonomous power supply of various objects.

State of the art

The prior art known autonomous small-sized thermoelectric current source (see RU 57969, CL H01L 35/00, publ. 2006).

A well-known autonomous small-sized thermoelectric current source contains, installed in the housing, a gravitational heat pipe with a liquid coolant and placed on top of it a thermoelectric battery with electrical connections, connected to the connector for connecting the consumer.

This current source is intended for autonomous power supply. The obtained original design of the known device made it possible to provide it with such properties as complete autonomy, small size, high reliability and ease of transportation due to light weight. However, this current source, to a greater extent, is intended for autonomous power supply of various small devices (communication equipment, batteries, household radio equipment, etc.), and as a result, its low output power in an extreme situation, is not suitable for maintaining the operability of large objects that require high capacities, such as power plants that supply electricity to individual industrial and individual buildings, transport facilities, metallurgical industry facilities, etc.

The original design of the current source is given by a central hollow column fixed between the sleeve coupling and the conical end sleeve, which is installed under the lower end of the middle transport part of the gravitational heat pipe, the mentioned end of which is rigidly connected to the free side of the connecting hole by a coupling, on which side a notch screen is fixed , having the form of a disk with a central landing hole, and additional heat dissipations are placed above it notch lamellar screens mounted on rods cantilever connected to the bottom of the housing located above said screens. At the same time, the heat-receiving tubes are made in the form of arches rotundo-shaped, placed around the said central column and connected by upper and lower ends with through holes in the lateral surfaces of the respective couplings, and the fins on the heat-receiving tubes are made in the form of washers strung on them. This original design of the known current source is associated with certain disadvantages, which are the complexity and complexity of its manufacture and, accordingly, the high cost of the resulting product.

The prior art method for the direct conversion of thermal energy into electrical energy and a generator for its implementation (see RU 2329562, CL H01J 45/00, publ. 2008).

The known invention relates to the field of direct conversion of thermal energy into electrical energy.

This generator is a sealed cylindrical housing with a device for entering the coolant flow from an external source and a device for outputting the spent coolant flow. Inside the case, thermionic elements are installed in the form of rings assembled from separate segments and connected into a single electrical circuit.

The technical result of the known solution is to increase efficiency and reduce overall dimensions.

Among the disadvantages of the known solutions, it is possible to note a complex structure containing a large number of structural elements and high material consumption.

The closest analogue of the proposed technical solution can be considered a power plant, known from RU 2125165, class. F01K 25/00, publ. 1999 year

This installation relates to power engineering, namely to installations for converting low-grade heat into electrical energy.

The well-known power plant is made in the form of a closed circulation circuit, including a heat engine with a power load, a tank filled with a working fluid with a boiling point not higher than 50 ° C, providing heating and cooling of the said working fluid, heat exchangers at the inlet and outlet of the engine, providing circulation working fluid supercharger and connecting pipelines. In this case, the heat carrier - the refrigerant of one of the heat exchangers is the flow of water from a natural reservoir, and the heat carrier - the refrigerant of another is the flow of atmospheric air surrounding the reservoir.

This installation is efficient and reliable during operation throughout the year, however, its field of application is quite narrow and is limited by the fact that it is installed directly on the reservoir and is able to provide electric power only to objects located in the immediate vicinity of it.

Utility Model Disclosure

The objective of the proposed utility model is to increase the generated electric power and, accordingly, the efficiency of the thermoelectric generator.

The technical result of the proposed utility model, which is objectively manifested during its operation, is an artificial increase in the temperature difference between hot and cold junctions of the thermopile of a thermoelectric generator.

The specified technical result, which solves the problem, is achieved by the fact that the thermoelectric generator contains a heat receiver, structural fasteners that are in thermal conjugation with each other and heat removal means, while the internal cavity of the heat removal means contains a liquid coolant boiling point, which is lower than the boiling point water under normal conditions, and is made with a degree of vacuum, providing the creation of artificial additional lowering the boiling point of the liquid eplonositelya.

The heat removal means is advantageously provided in the form of a heat pipe or finned radiator.

It is advisable if the heat removal means is made in the form of a heat pipe or finned radiator at the same time.

This thermoelectric generator, according to the proposed utility model, is aimed at solving the problem of the rational use of known phenomena to create an improved design of a thermoelectric generator with higher efficiency, and, accordingly, with a higher generated electric power.

The proposed thermoelectric generator with heat removal means, the inner cavity of which contains a liquid coolant, the temperature of which is lower than the boiling point of water under normal conditions and additionally made with a degree of vacuum providing an artificial lowering of the boiling point of the coolant, is a device for the direct conversion of thermal energy into electrical energy based on the application of the Seebeck effect, which consists in the manifestation of EMF in a closed circuit of two dissimilar materials with word, that contact points are maintained at different temperatures. This effect occurs due to the temperature dependence of the energy of free electrons and the so-called "holes". At the contact points of various materials, the charges pass from the conductor, where they had a higher energy, to the conductor with a lower charge energy. If one contact is heated more than the other, then the difference in the energy of the charges between the two substances is greater on the hot contact than on the cold, as a result of which a current arises in a closed circuit.

As a result of the fact that the proposed utility model includes a heat receiver, structural fasteners that are in thermal conjugation with each other and heat removal means, an internal cavity that contains a liquid coolant, a boiling point which is lower than the boiling point of water and is made with a degree of vacuum, providing an additional artificial lowering of the boiling point of the liquid coolant, an increase in the temperature difference between hot and cold junctions of the thermal battery was recorded, which in turn, provoked an increase in the generated electric power of the generator.

These essential features of the proposed thermoelectric generator form a set of essential features necessary and sufficient to achieve a technical result, which consists in increasing the temperature difference between hot and cold junctions of the thermopile, which actually increases the generated electric power of the generator and accordingly increases its efficiency.

Brief Description of the Drawings

In FIG. 1 shows a general view of a thermoelectric generator;

In FIG. 2 shows the dependence of the generated electric power.

Utility Model Implementation

The utility model is illustrated by a specific implementation example, which, however, is not the only possible, but clearly demonstrates the achievement of a given set of essential features of a given technical result.

The thermoelectric generator comprises a heat sink 1, a burner 2, a heat battery 3, heat removal means 4, a heating zone 5, a boiling zone 6, a condensation zone 7, and a cooling zone 8.

The principle of operation of the proposed generator is as follows.

In the proposed design of the thermoelectric generator, the heat receiver 1 (heating zone 5) is heated by combustion of natural (liquefied) gas using a burner 2. Heat removal (cooling zone 8) is provided by means of heat removal 4, made in the form of a heat pipe or finned radiator, the internal cavity, which contains the liquid coolant and is additionally made with a degree of vacuum, providing the creation of an artificial lowering of the boiling point of the liquid coolant. The required temperature of the heat receiver 1 is maintained according to the feedback principle: thermocouple-control-gas pressure adjustment.

It is known that the thermopower of a thermoelectric generator is directly proportional to _Δ T between hot and cold junctions of thermopile 3:

E _max = α × _Δ T.

The dependence of the generated electric power is shown in FIG. 2.

To ensure the effective operation of the thermoelectric generator, it is necessary to ensure the maximum temperature difference between the sides of the thermopile 3, for this it is necessary to supply heat Q _r to one side of it, and, on the other hand, to ensure efficient removal of thermal energy Q _x . In this case, the electric power is directly proportional to the square of the temperature difference _Δ T:

P = Q _r -Q _x = J ² R≈ _Δ T ²

At a fixed and controlled temperature on the hot side of the thermopile 3, maximum _Δ T can be achieved by lowering the temperature on the cold side of the thermopile 3.

The specified technical result is achieved by using the heat of vaporization (boiling) of the intermediate liquid coolant with a boiling point below the boiling point of water under normal conditions (i.e. below 100 ° C). For this, a thermoelectric generator uses heat removal means 4 with an internal cavity and liquid in it with a low boiling point in normal climatic conditions. In this case, the internal cavity of the heat removal means 4 is sealed. In addition, the method of creating a certain degree of vacuum in the internal cavity of the heat removal means 4 is additionally used to artificially lower the boiling point of the liquid.

Comparative tests of the proposed thermoelectric generator with generators known from the prior art were carried out under the following conditions:

- tested were two designs of the proposed thermoelectric generator - with means of heat dissipation 4, made in the form of a heat pipe and in the form of a fin radiator and two designs of traditional known thermoelectric generators;

- the heating temperature of the hot side in all samples was achieved by the same burned in-person device and heat receiver;

- the ambient temperature did not change;

- load resistance did not change.

Test Results:

- on the cold side of the thermopile of traditional known thermoelectric generators, a temperature of 120 ° C was established (at a fixed temperature on the hot side at the operating point). The generated electric power was 150 W;

- on the cold side of the thermopile 3 of the proposed thermoelectric generators, a temperature of 86 ° C was established. The generated electric power was 180 W;

Thus, the proposed design of the thermoelectric generator, namely, the set of its essential features, provides an artificial increase in the temperature difference between hot and cold junctions of its thermopile 3, which actually solves the problem of increasing the generated power and efficiency.

The desired technical result is achieved thanks to the formulated set of essential features, clearly presented below:

- thermoelectric generator contains structural fasteners that are in thermal conjugation with each other, a heat sink 1 and heat removal means 4;

- the internal cavity of the heat removal means 4 contains a liquid coolant boiling point, which is lower than the boiling point of water under normal conditions;

- additionally, the internal cavity of the heat removal means 4 is made with a degree of vacuum, ensuring the creation of an artificial lowering of the boiling point of the liquid coolant.

The proposed thermoelectric generator, according to the proposed utility model, can find wide application in the fuel and energy sector.

Claims (3)

1. Thermoelectric generator containing a heat sink, a thermopile, structural elements that are in thermal conjugation with each other, and heat removal means, the internal cavity of which contains a liquid coolant whose boiling point is lower than the boiling point of water under normal conditions, and is made with a degree of vacuum, providing the creation of an artificial lowering the boiling point of the liquid coolant. 2. The thermoelectric generator according to claim 1, characterized in that the heat removal means is made in the form of a heat pipe. 3. The thermoelectric generator according to claim 1, characterized in that the heat removal means is made in the form of a fin radiator.

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