RU2357327C1 - Thermo-electrical battery - Google Patents

Abstract

FIELD: instrument making.

SUBSTANCE: invention relates to thermo-electrical instruments, in particular, to thermo-electrical batteries (TEB). The device structure surface formed by the TEB branches, apart from the areas adjoining the extending parts of switching plates, is coated with heat insulation dielectric material. The area not coated with the said material is determined as the product of thermal element branch thickness by 1/4 of its height. Note here that heat is picked up from the switching plates and adjacent areas via evaporation of heat carrier effected by appropriate evaporation system. Heat is removed from cooled switching plates and adjacent areas of the TEB branches by forcing fluid in contact with the elements in fluid-type heat exchanger.

EFFECT: higher efficiency of removing heat from TEB hot contacts (feeding it thereto).

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Description

The invention relates to thermoelectric instrumentation, in particular to the construction of thermoelectric batteries (TEB).

The prototype of the invention is the thermopile, described in [1]. A fuel cell consists of semiconductor thermoelements connected in series to an electric circuit, each of which is formed by two branches (columns made either cylindrical or in the form of a rectangular parallelepiped) made of a p- and n-type semiconductor, respectively. The branches of the thermocouples are interconnected by means of patch plates, the p-type and n-type branches contacting the end surfaces with two opposite surfaces of the connecting plate, respectively. The patch plates have a slightly larger area than the cross-sectional area of the branches, as a result of which they protrude beyond the surface of the structure formed by the thermopile branches, moreover, the odd patch plates protrude over one surface of the structure, and the even patch plates over the other. Accordingly, heat is removed and supplied from the protruding parts of the switching plates due to air or liquid heat exchange.

A disadvantage of the known design is the removal (supply) of heat only from the surface of the protruding parts of the patch plates, while due to the thermal conductivity there is also heating (cooling) of the adjacent areas of the branches of thermocouples.

The aim of the invention is to increase the efficiency of removal (supply) of heat from the hot (cold) contacts of the fuel element due to the removal (supply) of heat also from neighboring areas of the branches of thermocouples.

The goal is achieved in that the surface of the structure formed by the thermopile branches, with the exception of areas adjacent to the protruding parts of the connection plates, is covered with a layer of heat-insulating dielectric material. The area not covered by the heat-insulating layer of dielectric material is defined by the product of the thermopile branch thickness by _^1/4 of its height. At the same time, heat is removed from the hot connection plates, as well as from areas adjacent to them, due to evaporative cooling realized by the evaporative system. Heat is removed from the cooled patch plates and areas adjacent to them by pumping liquid in a liquid heat exchanger in contact with them.

The design of the thermoelectric battery is shown in Fig.1-2. TEB consists of alternating branches connected in series into the electric circuit by means of switching plates 1 and 2, made of p-type 3 and n-type 4 semiconductor, respectively. The electric connection of the branches is carried out by means of contact p-type branch 3 - switching plate 1 or 2 - branch n-type 4, where the p-type 3 branch is in contact with the end surface from one of the surfaces of the patch plate, and the n-type 4 branch is on the other. Each branch in the thermopile is in contact with opposite end surfaces with two switching plates 1 and 2. The switching plates 1 and 2 have an area slightly larger than the cross-sectional area of the p- and n-type branches 3 and 4, as a result of which their ends protrude beyond the surface of the structure formed by the branches of the thermopile. The ends of the odd patch plates 1 protrude beyond one surface of the structure, and the ends of the even patch plates 2 protrude from the other.

The surface structure formed TEB branches, except in areas close to protrusions switching plates 1 and 2 is covered with a layer of thermally insulating dielectric material 5. The area not covered by the heat-insulating layer of dielectric material 5 is determined by the product of the thermopile branch thickness for _^1/4 of its height. The heat is removed from the hot patch plates, as well as from areas adjacent to them, by evaporative cooling implemented by the evaporative system 6. The heat (“cold”) is removed from the cooled patch plates and the areas adjacent to them by pumping liquid in contact with them liquid heat exchanger 7.

TEB operates as follows.

When a constant electric current supplied from an electric energy source passes through the thermopile, between the switching plates 1 and 2, which are contacts of the p- and n-type branches 3 and 4, a temperature difference occurs due to the release and absorption of Peltier heat. With the polarity of the electric current indicated in FIG. 1, the odd patch plates 1 are heated and the even ones are cooled 2. The heat is removed from the hot patch plates 1 by evaporative cooling implemented by the vaporization system 6. Heat is removed from the cold patch plates by pumping liquid into contacting them with a liquid heat exchanger 7. Improving the efficiency of heat removal from hot and cold contacts of thermopiles takes place due to its removal from nearby to the connecting plates of the surface areas of the structure formed by the thermopile branches. At the same time, thermal insulation 5 serves to reduce heat gain from the environment.

Literature

1. Pozdnyakov BS, Koptelov EA Thermoelectric power. M .: Atomizdat, 1974.

Claims (1)

A thermoelectric battery, consisting of semiconductor thermoelements connected in series to the electrical circuit by means of connecting plates, each of which is formed by two branches made of p-type and n-type semiconductor, respectively, and p-type and n-type branches contact end surfaces respectively with two opposite the surfaces of the patch plate, the patch plates have a slightly larger area than the cross-sectional area of the branches, as a result of which they protrude beyond the surface of the structure formed by the branches of the thermoelectric battery, characterized in that the surface of the structure formed by the branches of the thermopile, with the exception of areas adjacent to the protruding parts of the connection plates, is covered with a layer of heat-insulating dielectric material, and the area not covered by a layer of heat-insulating dielectric material is determined by the product of the thickness branches of the thermocouple to 1/4 of its height, while taking heat from hot patch plates, as well as from areas adjacent to them It is due to the evaporative cooling implemented by the evaporative system, and heat is removed from the cooled switching plates and the areas adjacent to them by pumping the liquid in the liquid heat exchanger in contact with them.

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