FR3013429A1 - THERMO ELECTRIC MODULE AND THERMO ELECTRIC DEVICE COMPRISING AT LEAST ONE SUCH MODULE. - Google Patents

Abstract

The invention relates to a thermoelectric module comprising a circulation channel of a first fluid, said to be hot, and / or a circulation channel of a second fluid, said to be cold, and a plurality of electric thermoelectric elements (4), capable of generating an electric current under the action of a temperature gradient exerted between two of their faces, said contact faces (3a, 3b), said module further comprising an electrical connection means (20) interconnecting said contact faces (3a, 3b) of two adjacent thermoelectric elements (4), said electrical connection means (20) being in heat exchange relation with one of the hot or cold channels, characterized in that the means electrical connection means (20) comprises between the adjacent electrical thermoelectric elements (4) a portion (24) arranged to mechanically deform, said electrical connection means (20) being planar. The invention also relates to a thermoelectric device comprising such a module.

Description

Thermoelectric module and thermoelectric device comprising at least one such module. The present invention relates to a thermoelectric module and a thermoelectric device, in particular for generating an electric current in a motor vehicle, comprising at least one such module. Currently, it has already been proposed electric thermo modules using so-called electric thermo elements, for generating an electric current in the presence of a temperature gradient between two of their opposite faces, said first and second faces, according to the known phenomenon as the Seebeck effect. These modules are arranged to be inserted into devices comprising a stack of first tubes, intended for the circulation of the exhaust gases of an engine, and second tubes, intended for the circulation of a heat transfer fluid of a cooling circuit. cooling. The electrical thermo elements are sandwiched between the tubes so as to be subjected to a temperature gradient from the temperature difference between the hot exhaust gases and the cold cooling fluid.

The electric thermoelectric elements arranged in such modules are of two types: P-type elements making it possible to establish an electrical potential difference in a positive direction, when they are subjected to a given temperature gradient, N-type elements allowing the creation of an electrical potential difference in an opposite direction, called negative, when they are subjected to the same temperature gradient. The P type thermoelectric elements alternate with the N type thermoelectric elements. They are grouped in pairs, each pair being formed of a P type thermoelectric element and an N type thermoelectric element. the module for enabling a flow of current between the first faces of the thermoelectric elements of the same pair and a flow of current between the second faces of each of the electric thermo elements of two neighboring pairs. In other words, the current flows in series through the electric thermoelectric elements alternatively passing from a P type thermoelectric element to an N type thermoelectric element. For this, the module comprises a plurality of electrical tracks, each of which between it connecting the first faces of the electric thermo elements of the same pair or the second faces of each of the electric thermo elements belonging to two neighboring pairs to allow the flow of current described above. It is known to assemble the electric thermo elements to the first and second electrical tracks by a heat treatment. During this heat treatment, the electric tracks, made of metal, and the electric thermoelectric elements are caused to expand under the effect of the temperature freely before the joining takes place. Once the parts to be assembled have reached the correct temperature, the joining is achieved and then we begin to cool all.

A disadvantage comes from the fact that the electric tracks retract and regain their original dimensions with the return to room temperature and thus bring the two electric thermo elements to which they are secured. Thus, the electrical tracks connecting the first faces of the electric thermo elements of the same pair bring the elements of the same pair to each other while the tracks connecting the second faces of the electric thermo elements belonging to two neighboring pairs bring the thermoelectric elements of two neighboring pairs so that they remove the thermoelectric elements of the same pair. The thermoelectric elements are then subjected to opposite stresses, one acting on their first face and the other on their second face, leading to a shear which may damage them, in particular by creating cracks and / or breaks. This risk also exists when the operating thermoelectric module is subjected to a large difference in temperature between its cold side and its hot side, which is typically the case when the hot face of the device is subjected to temperatures greater than 250 ° C. vs. By reaching these temperatures, the electrical tracks secured to the hot-side electric thermo elements expand more than those joined to the cold-side electric thermo elements, which may damage the electric thermoelectric elements in the same manner as described above. The invention aims to improve the situation. To this end, it proposes a thermoelectric module comprising a circulation channel of a first fluid, said to be hot, and / or a circulation channel of a second fluid, said to be cold, and a plurality of electric thermoelectric elements, capable of generating an electric current under the action of a temperature gradient exerted between two of their faces, said contact faces, said module further comprising an electrical connection means interconnecting said contact faces of two adjacent thermoelectric elements, said electrical connection means being in heat exchange relation with one of the hot or cold channels, characterized in that the electrical connection means comprises between the adjacent electrical thermoelectric elements a portion arranged to deform mechanically, said connection means electric being plane.

Thus, thanks to the invention, the contraction of the electrical connection means during the cooling of the thermoelectric module and / or its expansion when the thermoelectric module is subjected to high operating temperatures are damped by the portion arranged to deform mechanically . In addition, the connection means being flat, that is to say flat, it can be arranged above and / or below the adjacent electrical thermo elements that connects so that the portion arranged to deform mechanically be arranged between these two thermoelectric elements, while leaving free space between these two thermoelectric elements. In other words, said portion arranged to be deformed mechanically is more precisely located between said contact faces. It is thus possible to reduce the empty space between the electric thermoelectric elements and bring them closer together as much as desired. It is thus possible to increase the density of electric thermoelectric elements in the electrical module so as to improve the efficiency of the thermoelectric module. The electrical connection means is, for example, an electrical track. Advantageously, the portion arranged to deform mechanically comprises a recessed portion. The portion arranged to deform mechanically consists in particular of said recessed portion. The recessed portion makes it possible to damp the contraction of the electrical connection means during the cooling of the thermoelectric module and / or its expansion when the thermoelectric module is subjected to high temperatures. Indeed, the recessed portion is less mechanically resistant than the rest of the electrical connection means and can therefore be deformed, that is to say here to expand and contract more easily. The recessed portion includes void portions and material bridging portions, so that the material bridges deform more easily. Thus, the recessed portion absorbs the stresses exerted on the thermoelectric elements by the electrical connection means so that the electric thermo elements undergo less shearing forces between their contact faces, thus reducing the risk of cracking or breaking. A recessed portion is understood to mean a portion in which the material is not continuous. According to one aspect of the invention, the recessed portion comprises a mesh portion.

According to an exemplary embodiment of the invention, the recessed portion comprises a portion of expanded metal. Advantageously, the electrical connection means comprises a first solid wall and a second solid wall, the portion arranged to deform mechanically connecting the first to the second solid wall. Full is understood to mean that the walls do not include an opening. The solid walls are, in particular, flat.

According to one aspect of the invention, the first and second solid walls comprise a first planar face, the first planar face of the first solid wall is in contact with a first of said adjacent electrical thermoelectric elements and / or the first planar face of the second solid wall is in contact with the other of said adjacent thermoelectric elements.

According to an exemplary embodiment of the invention, the surface of the first planar face of the first solid wall is greater than or equal to the contact face of the first thermoelectric element and / or the surface of the first planar face of the second wall. full is greater than or equal to the contact face of the second thermoelectric element. The solid walls on the active faces of the electric thermo elements are preferably chosen to ensure a good electrical connection between the electric thermoelectric elements and the electrical connection means.

Advantageously, the first of said electric thermo elements is of type P and the second of said electric thermo elements is of N. According to one aspect of the invention, the portion arranged to deform mechanically covers a surface separating the two adjacent thermoelectric elements. The invention makes it possible to take advantage of all the available surface area between two adjacent thermoelectric elements so as to be able to damp the maximum of the expansion and contraction of the electrical connection means.

According to an exemplary embodiment of the invention, the electrical connection means consists of a material having elastic properties. The elastic properties of the material contribute to the damping of the expansion or contraction of the electrical connection means.

Advantageously, the electrical connection means comprises aluminum, copper and / or nickel and / or one or more of their respective alloys. According to one aspect of the invention, the thickness of the electrical connection means 25 is between 50pm and 300pm. According to an exemplary embodiment of the invention, the first and the second solid walls comprise a second planar face opposite to the first planar face and in heat exchange contact with the hot channel or the cold channel. In a variant, the electrical connection means is in contact with a thermal conduction means, said thermal conduction means being an electrical insulator. The thermal conduction means is, for example, ceramic material.

Advantageously, the thermal conduction means is in contact with the hot channel or the cold channel. Said thermal conduction means is, for example, a layer of material coating said hot channel or said cold channel.

According to one aspect of the invention, the electric thermo elements are brazed to the electrical connection means, by their contact faces. According to an exemplary embodiment, the thermoelectric module comprises a said electrical connection means in heat exchange relationship and secured to at least the hot channel. In the case of an expansion due to the heat of the hot channel, the portion arranged to be deformed mechanically will thus dampen the thermal expansion of the electrical connection means in an optimized manner.

Advantageously, the thermoelectric module comprises a said electrical connection means in heat exchange relationship and secured to the hot channel and a said electrical connection means in heat exchange relationship and secured to the cold channel. It is advantageous to use similar electrical connection means hot side and cold side.

The invention also relates to a thermoelectric device, in particular for generating an electric current in a motor vehicle, comprising at least one module as described above.

The appended figures will make it clear how the invention can be realized. In these figures, identical references designate similar elements. Figure 1 illustrates in perspective, an example of a thermoelectric device according to the invention, shown in an exploded manner; Figure 2 is a schematic side view of a portion of a thermoelectric module comprising an electrical connection means according to the invention at room temperature before brazing; Figure 3 is a top view of the electrical connection means according to the invention.

Figures 4 and 5 are figures similar to Figure 2 showing said portion of the thermoelectric module soldering temperature (Figure 4) and at room temperature after soldering (Figure 5). FIG. 6 is an alternative embodiment of the thermoelectric module shown in FIG. 2. FIG. 7 is another alternative embodiment of the thermoelectric module shown in FIG.

As illustrated in Figure 1, a device according to the invention comprises one or more electric thermo modules. Each of the electric thermo modules comprises thermal conduction supports in contact with a hot or cold source, such as a plurality of tubes 1 for circulating a first fluid alternating with a plurality of tubes 2 for circulating a second fluid. Said tubes 1, 2 extend here parallel to each other in the same direction. The circulation tubes 1 of the first fluid are configured, for example, for the circulation of a fluid, said to be hot. It may be the exhaust gas of a motor vehicle engine. The circulation tubes 1 of the first fluid define one or more circulation channels of the first fluid, called hot channels. The circulation tubes 2 of the second fluid are configured, for example, for the circulation of a fluid, said cold, having a temperature lower than the temperature of the first fluid. It may be a coolant, such as a mixture of water and glycol, from, for example, a low temperature cooling loop of the vehicle. The circulation tubes 2 of the second fluid define one or more circulation channels of the second fluid, said cold channels.

Here, the circulation tubes 1 of exhaust gas are three in number and the circulation tubes 2 of the coolant are four in number. Said electric thermo modules furthermore comprise a plurality of elements, called electrical thermoelectric elements, making it possible to create an electric current from a temperature gradient applied between two of their faces, called first and second contact faces, provided in relation to each other. heat exchange with said hot and cold channels.

This is, for example, elements 4 of substantially parallelepiped shape (schematically visible in Figures 2 and 4 to 7) generating an electric current, according to the Seebeck effect. Such elements allow the creation of an electric current in a load connected between said opposed contact faces 3a, 3b. In a manner known to those skilled in the art, such elements consist, for example, of Bismuth and Tellurium (Bi2Te3). Said circulation tubes 1, 2 have, for example, a flattened section in an elongation direction, orthogonal to the direction of extension of the tubes. Said circulation tubes 1, 2 may thus be flat tubes. This means that they have two large parallel faces connected by short sides. The thermoelectric elements 4 are in contact with one and / or the other of the flat faces of the tubes 1, 2 by their contact faces 3a, 3b. Said tubes 2 intended for the circulation of the cold fluid consist, for example, of aluminum and / or of aluminum alloy. The tubes 1 intended for the circulation of hot fluid, consist, in particular, of stainless steel. They are formed, for example, by profiling, welding and / or brazing. Said device further comprises, for example, a manifold plate 15 at each end of said tubes 1 for circulation of the first fluid. Said collector plate 15 is provided with orifices 6 in which the ends of said tubes 1 for circulating the first fluid are inserted.

Said device may also comprise manifolds 7 in fluid communication with the end of said circulation tubes 1 of the first fluid and fixed to the collector plates 15 by means of screws 8. Said boxes comprise an orifice 16 for the inlet and or the output of the first fluid.

Said tubes 2 for circulating the second fluid may be provided at each of their end with collectors 9 allowing communication of said circulation tubes 2 of the second fluid and a manifold, not shown, of the second fluid via orifices 10 opening on a side face of the beam defined by the stack of tubes 1, 2 of circulation of the first and second fluid. As illustrated in FIG. 1, the electric thermoelectric elements are distributed in layers provided between the tubes 1 for circulating the first fluid and the tubes 2 for circulating the second fluid. Each ply 5 schematically represents a plurality of electric thermo elements arranged in a rectangular shape. In the thermoelectric device, electrical connections are established between the layers 5 of electric thermo elements. An electrical connector, not shown, allows the device to be connected to an external electrical circuit.

The thermoelectric elements may be, for a first part, elements of a first type, called P (referenced 4P), for establishing an electrical potential difference in a direction, said positive, when subjected to a given temperature gradient, and, for the other part, elements of a second type, called N (referenced 4N), allowing the creation of an electrical potential difference in an opposite direction, called negative, when they are subjected to the same temperature gradient. The thermoelectric elements applied on the same tube 1, 2 are electrically connected. In particular and as illustrated in FIGS. 2 and 4 to 7, the P type thermoelectric elements and the N type thermoelectric elements, provided between a same tube for circulating the first fluid and a same tube for circulating the second fluid, can be associated with each other so as to allow the flow of the series current from one element of the first type to an element of the second type. It is also possible to electrically connect the faces of electric thermo elements of the same type to a parallel assembly of said elements. The thermoelectric elements 4 thus associated form a basic conduction cell and the cells obtained may be associated in series and / or in parallel.

In these figures, the first contact face 3a of each electric thermo element is intended to be in heat exchange relation with the hot channel and the second contact face 3b of each thermoelectric element is intended to be in exchange relation. thermal with the cold channel. This creates the desired temperature gradient. Part of a thermoelectric module according to the invention is shown in FIGS. 2 and 4 to 7. The thermoelectric module comprises at least two of said electric thermo elements 4. In these figures, the P-type thermoelectric elements alternate with the N-type thermoelectric elements. They are grouped in pairs, each pair being formed of a P-type thermoelectric element and an N-type thermoelectric element. The module is configured to allow current to flow between them. first contact faces 3a of the thermoelectric elements of the same pair and a flow of current between the second contact faces 3b of each of the electric thermo elements of two neighboring pairs. In other words, the current flows in series through the electric thermoelectric elements alternatively passing from a P type thermoelectric element to an N type thermoelectric element. For this, the thermoelectric module comprises a plurality of electrical connection means. 20, 30 connecting the first contact faces 3a of the electric thermo elements of the same pair and the second contact faces 3b of each of the electric thermo elements belonging to two neighboring pairs to allow the flow of current described above. Two adjacent thermoelectric elements are connected by the electrical connection means 20, either by their first contact face 3a or by their second contact face 3b. According to the invention, at least one of the electrical connection means, said first electrical connection means 20, is plane and comprises a portion 24 arranged to deform mechanically, that is to say that it is able to deform . In the example shown in FIG. 2, the first electrical connection means 20 interconnect the electric thermoelectric elements 4 of the same pair, that is to say that they are positioned on the first faces 3a of the elements. 4. The first electrical connection means 20 are here in heat exchange relationship only with the hot channel or channels. The thermoelectric module may comprise other electrical connection means 30, said second electrical connection means 30. Here, the second electrical connection means 30 connect together the neighboring electrical thermo elements 4 belonging to neighboring pairs. The second electrical connection means 30 are here arranged to be in heat exchange relationship with the cold channel or channels. These are, for example, flat electrical tracks. The thermoelectric elements 4 and the electrical connection means are here represented at ambient temperature and before soldering, that is to say before joining. Said electrical connection means are here secured to the fluid circulation channels but they may alternatively be secured to fins or heat pipes, themselves ensuring the heat exchange relationship between said electric thermo elements and said channels. In other words, more generally, said thermoelectric elements are secured to a support in thermal contact with a cold source, on the one hand, and a hot source, on the other hand.

The first electrical connection means 20 comprise a first solid wall 22 and a second solid wall 23. The first solid wall 22 and the second solid wall 23 are located on the first contact faces 3a or on the second contact faces 3b of two adjacent 4 thermal thermo elements.

The portion 24 arranged to deform mechanically comprises a recessed portion 24. It consists here of the recessed portion 24. The recessed portion 24 connects the first to the second solid wall 22, 23. The recessed portion 24 and the solid walls 22, 23 are in the same plane. This recessed portion 24 extends between the two faces of the electric thermo elements 4 on which is disposed the first electrical connection means 20, that is to say that the recessed portion 24 is located between two adjacent thermoelectric elements. In other words, the recessed portion 24 protrudes from the solid walls 22, 23. Thus, the recessed portion 24 covers a surface separating two adjacent thermoelectric elements 4 connected by said electrical connection means 20. The electrical connection means 20 ) being planar, the surface covered by the recessed portion lies outside the space between two adjacent thermoelectric elements connected by said electrical connection means 20. Advantageously, the connection means 20 comprising the recessed portion 24 s extends above or below the electric thermo elements 4 but not between them so that the space between two electric thermo elements 4 connected by the same electrical connection means 20 is free. It is thus possible to have two electric thermoelectric elements 4 connected by the same electrical connection means 20 as close to one another as desired.

In these exemplary embodiments, the recessed portion 24 comprises a mesh part and / or an expanded metal part. It takes the form of a grid. The recessed portion 24 thus comprises empty spaces of material and bridges of material, advantageously flexible, connecting the solid walls.

The first and the second solid walls 22, 23 comprise a first planar face 25 in contact with the electric thermo elements 4 and a second flat face 26 opposite and parallel to the first planar face 25 and in heat exchange contact with the hot channel. or the cold channel. The first planar face 25 of the first solid wall 22 is in contact with a P type thermoelectric element and the first face 25 of the second solid wall 23 is in contact with an N type thermoelectric element. The first 25 and second 26 plane faces are interconnected by the material thickness of the solid walls 22, 23.

The thermoelectric module may comprise a thermal conduction means, not shown, in contact with the electrical connection means 20, 30, said thermal conduction means being an electrical insulator. The thermal conduction means is, for example, ceramic material. It allows the transfer of heat between the cold channel or the hot channel and the electrical connection means 20, which then transmits heat to the thermoelectric element 4 on which it is located. The thermal conduction means may be directly in contact with the cold channel or the hot channel. It may also be in heat exchange relation with the cold channel or the hot channel via the thermal conduction fins and / or heat pipes already mentioned, on which it is applied. As shown in FIG. 3, the first electrical connection means 20 is of substantially rectangular shape. The recessed portion 24 is here disposed in the center of the electrical connection means 20, crossing it parallel to a width of the rectangle. The recessed portion 24 is present here on a portion of the length of the rectangle formed by the electrical connection means 20. In another embodiment, it could be present throughout this length. The first electrical connection means 20 is, in particular, made of a material having elastic properties. It comprises, for example, aluminum, copper and / or nickel and / or one or more of their respective alloys. FIG. 4 shows the electric thermo elements 4 and the electrical connection means 20, 30 at soldering temperature. The electric thermo elements 4 are brazed to the electrical connection means 20, 30 by their contact faces 3a, 3b. The dotted lines represent the state of the electrical connection means 20, 30 at room temperature and the solid lines their states at soldering temperature. This difference in size is explained by the thermal expansion of the electrical connection means 20, 30. The electrical connection means 20, 30 expand mainly horizontally, that is to say parallel to the contact faces of the thermoelectric elements. on which they are located.

The connection between the electrical connection means and the electric thermo elements is done at this temperature and at this level of expansion of the electrical connection means 20, 30.

FIG. 5 represents the electric thermoelectric elements 4 and the electrical connection means 20, 30 once joined by brazing and returned to ambient temperature. Each of the electrical connection means 20, 30 tends to contract predominantly in the horizontal direction and to bring the two electric thermo elements 4 that connects. The recessed portion 24 on the first electrical connection means 20 then makes it possible to damp these opposing forces acting in a first horizontal direction at the level of the second contact face 3b of a thermoelectric element 4 and in a second horizontal direction, opposed to the first direction, at the same contact face 3b of the adjacent electric thermo elements 4, this returning to the initial position. Thanks to the invention, it avoids the shearing of the thermoelectric element 4 between its first and second contact faces. It may be noted that, thanks to the invention, when the module operates with a first fluid at high temperature, that is to say greater than 250 ° C, the recessed portions 24 can dampen the expansion that may be experienced by the first electrical connection means 20 in heat exchange relationship with the hot channel. Indeed, the recessed portions 24 can then dampen this expansion in the same manner as they do during soldering.

The positioning of the first electrical connection means 20 in heat exchange relation with the hot channel thus allows the recessed portions 24 to damp, on the one hand, the contraction of the first electrical connection means during the cooling which takes place after the brazing and, secondly, the expansion due to hot channel temperatures when the thermoelectric module operates and contraction when the thermoelectric module no longer works. According to an alternative embodiment of the invention illustrated in FIG. 6, the first electrical connection means 20 connect together the electric thermoelectric elements 4 belonging to the same pair and the adjacent electric thermo elements 4 belonging to two adjacent pairs. There are therefore here first electrical connection means 20 in heat exchange relationship with the hot channel and first electrical connection means 20 in heat exchange relationship with the cold channel.

It is also possible, without departing from the scope of the invention and as illustrated in FIG. 7, to have the first electrical connection means 20 only in thermal relation with the cold channel, that is to say here between two elements 4 neighboring electric thermo belonging to two adjacent pairs. The second connection means 30 here connect the electric thermo elements on the side of the hot channel.

Claims (15)

REVENDICATIONS1. Thermoelectric module comprising a circulation channel of a first fluid, said to be hot, and / or a circulation channel of a second fluid, said to be cold, and a plurality of electric thermoelectric elements (4), capable of generating a current electrical under the action of a temperature gradient exerted between two of their faces, said contact faces (3a, 3b), said module further comprising an electrical connection means (20) interconnecting said contact faces (3a , 3b) of two adjacent thermoelectric elements (4), said electrical connection means (20) being in heat exchange relation with one of the hot or cold channels, characterized in that the electrical connection means (20) ) comprises between the adjacent thermoelectric elements (4) a portion (24) arranged to deform mechanically, said electrical connection means (20) being planar. The thermoelectric module of claim 1, wherein the portion (24) arranged to deform mechanically comprises a recessed portion (24). The thermoelectric module of claim 2, wherein the recessed portion (24) comprises a mesh portion. The thermoelectric module of claim 2 or 3, wherein the recessed portion (24) comprises a expanded metal portion. The thermoelectric module according to any of the preceding claims, wherein the electrical connection means comprises a first solid wall (22) and a second solid wall (23), the portion (24) arranged to deform mechanically connecting the first (22) to the second solid wall (23). The thermoelectric module of claim 5, wherein the first and second solid walls (22, 23) comprise a first planar face (25), the first planar face (25) of the first solid wall (22) is in contact with a first of said adjacent thermoelectric elements (4) and / or the first planar face (25) of the second solid wall (23) is in contact with the other of said adjacent thermoelectric elements (4). 7. thermoelectric module according to claim 6, wherein the surface of the first planar face (25) of the first solid wall (22) is greater than or equal to the contact face of the first thermoelectric element (4) and / or the surface of the first planar face (25) of the second solid wall (23) is greater than or equal to the contact face of the second thermoelectric element (4). 8. Thermoelectric module according to claim 6 or 7, wherein the first of said thermoelectric elements (4) is of type P and the second of said thermoelectric elements (4) is of type N. 9. Thermoelectric module according to any one of the preceding claims, wherein the portion (24) arranged to deform mechanically covers a surface separating the two adjacent thermoelectric elements. Thermoelectric module according to any one of the preceding claims, wherein the electrical connection means (20) is made of a material having elastic properties. Thermoelectric module according to any one of the preceding claims, wherein the electrical connection means (20) comprises aluminum, copper and / or nickel and / or one or more of their respective alloys. 12. Thermoelectric module according to any one of the preceding claims, wherein the thickness of the electrical connection means is between 50pm and 300pm. 13. Thermoelectric module according to any one of the preceding claims, wherein the electric thermo elements (4) are brazed to the electrical connection means (20) by their contact faces (3a, 3b). 14. Thermoelectric module according to any one of the preceding claims, wherein the electrical connection means (20) is secured to the flow channel of the first or the second fluid. 15. Thermoelectric device, in particular for generating an electric current in a motor vehicle, comprising at least one module according to any one of the preceding claims.