RU2355075C1 - Thermoelectrochemical generator - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: present invention relates to conversion of thermal energy into electrical energy in a thermoelectrochemical generator. According to the invention, the thermoelectrochemial generator has an anode cavity, filled with sodium vapour at high pressure, a cathode cavity, filled with sodium vapour at low pressure, separated by a ceramic electrolyte base on sodium β-aluminium oxide, coated on the side of the anode and cathode cavities with a porous anode and cathode, a heater using isotope energy, and a cooling device. The thermoelectrochemical generator has a device for periodic removal of heat from one of the cavities to the cooling device. If one of the cavities is thermally insulated, heat is taken from the other cavity and during thermal insulation from the cooling device to the first cavity. For this purpose, the device has cylinder which turns 180 degrees, in contact with the cooling device and the indicated cavities. Part of the edge of the surface of this cylinder is made from heat-conductive material, while the other is made from heat-insulating material. On the side of the heat-conductive surface and on the side of the heat-insulating surface, the cylinder has current collectors, which are in contact with the anode and cathode cavities.

EFFECT: improved mass and weight characteristics and increased efficiency.

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Description

The invention relates to the field of direct conversion of thermal energy into electrical energy in a thermoelectrochemical generator (TEHG). In contrast to the well-known thermoelectric and thermionic machineless converters using isotope energy (1), TEHG has a higher efficiency due to the fact that the heated zone of the anode and cathode cavity is separated in space from the refrigerator, and the Lenz-Joule heat (2) generated during the generation of electricity at the maximum cycle temperature can be completely utilized in the thermodynamic cycle of the converter (analog) (3) )

The analogue contains an anode cavity filled with liquid sodium, separated by a β-alumina ceramic electrolyte from a cathode cavity filled with reduced pressure sodium vapor. The pressure in the cathode cavity determines the temperature of the refrigerator-condenser. Moreover, the supply of sodium from the capacitor to the anode cavity is carried out at the expense of a column of liquid sodium and in the conditions of terrestrial gravity an additional pumping system is not required. Relatively known converters of thermal energy into electrical analogue has a maximum value of efficiency However, in zero gravity conditions, he needs an additional pumping system that reduces the efficiency and weight and dimensional characteristics of the analogue.

Known TEHG (4) (prototype), a structural diagram of which is depicted in figure 1. It contains an anode cavity filled with sodium vapor of high pressure - 1, a cathode cavity filled with sodium vapor of low pressure - 2, a ceramic electrolyte based on β-alumina - 3, a ceramic ring - 4, a porous anode - 5, a porous cathode - 6, a heater - 7, refrigerator - 8, pump system - 9, evaporator - 10. The arrows indicate the flow of sodium and heat.

Due to the pressure difference between the anode and cathode cavity, an emf occurs. When the anode and cathode are closed through an external load, sodium in the form of ions flows through the ceramic electrolyte from the pressure cavity to the pressure cavity, generating an electric current. Since the prototype contains a pumping system, it can work in space. However, its presence in the prototype and the additional evaporator significantly worsens its weight and size characteristics and reduces the efficiency

To eliminate these shortcomings proposed TEHG, a structural diagram of which is presented in figure 2. The proposed TEHG contains an anode cavity filled with sodium vapor of high pressure - 1, a cathode cavity filled with sodium vapor of low pressure - 2, a ceramic electrolyte based on sodium B-alumina - 3, a ceramic ring - 4, a porous anode - 5, a porous cathode - 6 , a heater, in particular, using isotope-7 energy, a refrigerator -8, a cylinder -9 rotating through 180 degrees, a thermally conductive part of the cylinder’s generatrix surface 10, a thermally insulating part of the cylinder’s generatrix-surface, 11, current collector, contacting with the surface of the anode cavity - 12, the collector in contact with the surface of the cathode cavity - 13, arrows indicate heat fluxes.

The proposed thermoelectrochemical generator containing an anode cavity filled with high pressure sodium vapor, a cathode cavity filled with low pressure sodium vapor, separated from each other by a ceramic electrolyte based on sodium β-alumina, coated on the side of the anode and cathode cavity with a porous anode and cathode, a heater, using, in particular, isotope energy and a refrigerator, it differs in that it contains a device for periodically removing heat from one of the cavities to the refrigerator with thermal insulation and from the refrigerator to another cavity, then heat removal from the other cavity during thermal insulation of the first cavity, for which this device contains a 180-degree rotating cylinder in contact with the refrigerator and the indicated cavities, moreover, part of the forming surface of this cylinder is made of heat-conducting material, and the other part its forming surface is made of thermally insulating material, while the specified cylinder from the side of the anode cavity and from the side of the cathode cavity contains down conductors in contact with these foul.

The proposed TEHG works as follows. Sodium, located in a thermally insulated cavity, heats up and evaporates. The vapor pressure of sodium in this cavity becomes greater than the vapor pressure of sodium in another cooled cavity, which contacts the heat-conducting part of the cylinder forming with the refrigerator. Due to the pressure difference between these cavities, an EMF occurs. When the electrodes are closed through an external load, sodium in the form of ions flows through the ceramic electrolyte from the pressure cavity to the pressure cavity. When sodium is produced in a thermally insulated cavity, the cylinder rotates through 180 degrees with its thermally conductive surface in contact with this cavity and the refrigerator, and in the thermally insulated surface it contacts the other cavity, thermally insulating it from the refrigerator. Thus, the first cavity becomes cathode, and the second cavity becomes anode. The cycle repeats. In this case, the collector from the side of the thermally insulated surface of the cylinder will always be negative, and the collector from the side of the thermally conductive surface of the cylinder will be, respectively. This simplifies the switching of TEHG in the battery. The proposed TEHG due to the lack of an evaporator and a pumping system has higher weight and dimensions and a higher efficiency relatively well-known space machineless transducers. Therefore, the proposed TEHG may find application for powering autonomous space power plants, in particular for powering navigation systems.

Information sources

1. W. Corliss, D. Horvey. Sources of energy on radioactive isotopes "Mir", Moscow, 1967, 146-171.

2. L.N. Antropov. Theoretical electrochemistry. - M.: "Higher School", 1975, 19-21.

3. The journal "Engineer", No. 4, 2004, 36-37.

4. Journal of Power Sources 96 (2001), 343-351.

Claims (1)

A thermoelectrochemical generator containing an anode cavity filled with high pressure sodium vapors, a cathode cavity filled with low pressure sodium vapors, separated from each other by a ceramic β-alumina based electrolyte, coated with a porous anode and cathode on the side of the anode and cathode, a heater using in particular, isotope energy, and a refrigerator, characterized in that it comprises a device for periodically removing heat from one of the cavities to the refrigerator, while thermally insulating the other heat transfer from another cavity, when thermally insulated from the refrigerator of the first cavity, for which this device contains a 180 ° rotating cylinder in contact with the refrigerator and the indicated cavities, the part of the forming surface of this cylinder being made of heat-conducting material, and the other part of its forming the surface is made of heat-insulating material, wherein said cylinder on the side of the heat-conducting surface and on the side of the heat-insulated surface contains down conductors in contact with anode and cathode cavities.

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