RU51287U1 - THERMOELECTRIC GENERATOR BATTERY - Google Patents

Abstract

The invention relates to electrical engineering, in particular to thermoelectric devices, and can be used in refrigeration appliances, in systems of electrochemical protection of gas pipelines from destruction as a result of local corrosion. The thermoelectric generator battery contains thermomodules with semiconductor branches of n- and p-type conductivity with internal electrically conductive connections of the branches, switching elements of thermomodules for their connection with each other and current leads, a telescopic jacket made in the form of external and internal tubular shells. Thermal modules are made in the form of a split washer, which are connected in series by beam edges. The switching elements of the thermal modules are made in the form of sail-like plates placed along the washer cut, connecting the adjacent thermal modules in parallel so that they form a series connection of two adjacent pairs of thermal modules with the possibility of forming a single electrical circuit.

Description

The invention relates to electrical engineering, namely to thermoelectric devices, and can be used in refrigeration appliances, in systems for the electrochemical protection of gas pipelines from destruction as a result of local corrosion, in autonomous sources of electricity.

Currently, a rather urgent task is the development of small-sized, highly reliable, high-efficiency autonomous energy sources. Using the principle of direct conversion of thermal energy into electrical energy, for example, in thermal modules, allows us to solve the problem.

Among the known systems using this principle with electric power up to several kilowatts, long life (more than ten years), high reliability, and autonomy, only systems with thermoelectric converters currently have them, which makes them most preferred for use as autonomous sources of current and heat or sources of cold.

Thus, a thermoelectric battery [1] is known, which contains semiconductor branches of p- and n-conductivity, switching busbars, current leads, metal heat transfers and means for compensating thermoelectric voltages, which is made in the form of a layer of heat-conducting elastic insulating material located between the switching buses and heat transfers.

A disadvantage of the known thermoelectric battery is low efficiency.

The closest in technical essence to the claimed object and having a higher efficiency is a battery of thermoelectric elements [2], selected as a prototype.

This device includes film or lamellar or rolled semiconductor branches with n- and p-types of conductivity and current collection devices, equipped with an internal electrically conductive layer, mainly metal, with the formation of a bipolar system, while semiconductor branches with n- and p-types of conductivity deposited on the front surfaces of the electrically conductive layer, and at the metal-semiconductor interfaces, quasi-two-dimensional structures of electric charges are formed. The thermoelectric element can be made in the form of a tape or film, mainly rolled up.

Bipolar thermoelectric elements are connected into the battery in a sequential roll overlay with the formation of a multilayer structure with alternating layers. An electrically conductive layer of graphite lubricant or metal-graphite composites is placed between two successively mated thermocouples. The thermocouples are connected to the battery under high pressure in a special gas medium, and the monitoring in the process of creating electrical parameters is not accurate enough. Semiconductor branches can be made by sputtering, electric deposition, or ion implantation.

The disadvantages of this design are as follows. Low mechanical strength and high brittleness of semiconductor branches, through each of which all loads are transmitted during bending, compression and tension. Such a thermoelectric battery has low strength and can be destroyed by vibration and external loads. Another disadvantage of this design is the complex manufacturing technology, due to the use of complex extremely expensive technological equipment, expensive materials and the creation of a special gas environment to enable the creation of a thermal battery specified in the patent design.

The problem to which the invention is directed, is to create an inexpensive, simple in design and highly efficient thermoelectric generator battery with high mechanical strength, while having high reliability during operation. In this case, the achievement of the following technical and economic results should be ensured:

- improvement of technical and operational characteristics;

- simplicity of design;

- convenience and high reliability during operation.

The essence of the invention lies in the fact that a thermoelectric generator battery containing thermal modules with many semiconductor pairs of branches of n- and p-types of conductivity with internal electrically conductive connections of the branches, as well as switching elements of thermomodules for connecting them to each other and current leads, in contrast to the prototype, according to According to the invention, it is equipped with a telescopic jacket made in the form of an outer and inner tubular shells installed one in the other so that a cavity is formed between them to accommodate thermomodules, each of which is made in the form of a split washer, composed of serially connected n- and p-type branches, each of which has the shape of arched bent bars installed along an arcuate generatrix with a gap between adjacent branches, while the internal electrically conductive connections of the branches are made in the form of beams ribs mounted on the outer and inner sides of the said split washer, each beams rib connecting in series the n-type of one semiconductor branch with the p-type of adjacent th branch, wherein the switching elements are designed as thermal modules parusoobraznyh plates, for example made of copper, arranged along the cutting washer, parallel connecting adjacent thermal module so as to form a series connection of two adjacent pairs of thermal modules to form a single electrical circuit.

The claimed technical solution has significant differences from the prototype, i.e. meets the criterion of "novelty" and does not follow explicitly from the prior art, i.e. meets the criterion of "inventive step" and is used in industry, i.e. characterized by "industrial applicability".

For a better understanding of the essence of the claimed invention, you can refer to the following design details, illustrated by the relevant drawings, namely:

- figure 1 is a General view (axonometric image) of a thermoelectric generator battery;

- figure 2 - thermoelectric generator battery disassembled (axonometric image);

- figure 3 is a cross section of a thermoelectric generator battery along a central geometric axis;

- figure 4 - section aa in figure 3

Thermoelectric generator battery 1 contains (see Figs. 1-4) thermomodules 2 with many semiconductor pairs of branches of n- and p-types of conductivity (in this case, 8 pairs of semiconductor branches) with internal electrically conductive connections of the branches, switching elements 3 of thermomodules 2 for them interconnections and current leads 4.

The thermoelectric generator battery 1 is equipped with a telescopic jacket 5, made in the form of an outer 6 and an inner 7 tubular shells. The outer 6 and inner 7 tubular shells are installed so that a cavity 8 is formed between them to accommodate the thermal modules 2 (see Fig.1-2).

Each of the thermal modules 2 is made in the form of a split washer 9. The split washer 9 is composed of semiconductor pairs of n- and p-type branches, each of which has the shape of an arcuately bent bar 10 (see Figs. 3-4).

The internal conductive connections of the semiconductor branches are made in the form of beams ribs 11 and are placed on the outer 6 and inner 7 sides of the split washer 9. Each beams rib 11 connects in series semiconductor branches of n- and p-types of conductivity (see figure 2).

The switching elements 3 of the thermal modules 2 are made in the form of sail-like plates 12, for example, copper. Sail-like plates 12 are placed along the section of the washer 9 (in this case, the number of sail-like plates coincides with the number of pairs of semiconductor branches). The switching elements 3 in parallel connect adjacent thermal modules 2 (see Fig.1-2). Those. the thermoelectric generator battery is composed of 8 pairs of parallel connected thermal modules 2, which form a series connection of two adjacent pairs of thermal modules 2 with the possibility of forming a single electrical circuit.

The execution of the branches of the thermomodule 2 in the form of an arcuately bent bar 10, and their joints in the form of beam ribs 11, as well as giving a sail-like shape to the connection elements of the thermomodules 2 made it possible to increase the mechanical strength of the claimed design, and at the same time increase the mechanical strength, increased reliability

electrical circuit i.e. the design solution has significantly increased the efficiency of the device as a whole.

A prototype thermoelectric generator battery was manufactured. At present, preparations are underway for the production of serial products.

The operation of the thermoelectric generator battery can be considered in the following example (see figure 1-4).

Example: A thermoelectric generator battery 1 is mounted on a heat source having a cylindrical shape. A cold radiator is mounted on the outside of the thermoelectric generator battery 1.

Heat from the heat source enters the internal conductive connections of the semiconductor branches - beams ribs 11. Then, through the beams ribs 11, heat enters the thermal modules 2, and from them to the external conductive connections of the semiconductor branches.

At the same time, due to the Seebeck effect (the occurrence of an electromotive force in an electric circuit consisting of heterogeneous conductors connected in series, the contacts between which are at different temperatures), an electric current arises in the circuit of the split washers 9 of the thermoelectric generator battery 1, which through current leads 4 It is brought to the consumer in the established mode.

From the foregoing, the following advantages of the proposed thermoelectric generator battery are obvious:

- the design is compact with increased strength and low cost compared to the known ones;

- unlimited storage period at full readiness for work at any time;

- does not require special maintenance;

- completely silent in operation due to the lack of moving parts;

- long service life;

- improved specifications.

SOURCES OF INFORMATION USED IN THE DESCRIPTION OF THE INVENTION:

1. Thermoelectric battery.

RF patent №2142177, M. cl. H 01 ³⁵ L / _02, H 01, L _^35/32, 27.11.1999;

2. Thermoelectric element, battery of thermoelectric elements and method for their manufacture.

RF patent No. 2010396, M. cl. H 01 ³⁵ L / _02, H 01 L _^35/28, H 01 L _^35/34, 30.03.1994 (prototype).

Claims (1)

Thermoelectric generator battery containing thermal modules with many semiconductor pairs of branches of n- and p-types of conductivity with internal electrically conductive connections of the branches, as well as switching elements of thermomodules for connecting them together and current leads, characterized in that it is equipped with a telescopic jacket made in the form of an external and inner tubular shells installed one in the other so that a cavity is formed between them to accommodate thermal modules, each of which is made in the form of a split washer composed of serially connected n- and p-type branches, each of which has the shape of arched bent bars installed along an arcuate generatrix with a gap between adjacent branches, while the internal electrically conductive connections of the branches are made in the form of beam edges mounted on the outer and inner sides the said split washer, wherein each beams rib connects in series the n-type of one semiconductor branch with the p-type of the neighboring branch, while the switching elements of the thermal modules are made in Idea of sail-like plates, for example, made of copper, placed along the washer section, in parallel connecting adjacent thermal modules so that they form a series connection of two adjacent pairs of thermal modules with the possibility of forming a single electrical circuit.