WO2017149048A2 - Thermoelectric device and thermoelectric generator comprising such a device - Google Patents

Abstract

The invention relates to a thermoelectric device (10) comprising a plurality of thermoelectric modules (20), each of said modules (20) including a thermoelectric element (22) which can generate an electric current under the action of a temperature gradient exerted between two of the faces thereof, on contact with a cold source (F1) and a heat source (F2), said thermoelectric device also comprising a device for the treatment of toxic compounds. The invention also relates to an associated thermoelectric generator.

Description

 Thermoelectric device and thermoelectric generator comprising such a device

In the automotive field, thermoelectric devices have already been proposed using elements, called thermoelectric elements, making it possible to generate an electric current in the presence of a temperature gradient between two of their opposite faces according to the phenomenon known as the effect. Seebeck. These devices are also called thermoelectric generators.

 It is known to position these thermoelectric generators in a motor vehicle exhaust line, or even in the recirculated exhaust gas circuit for motor vehicles having such a circuit between the exhaust and the intake of the engine. The objective is the use of the exhaust heat of motor vehicles to generate electrical energy.

 The treatment of the exhaust gas is then necessary, in particular to prevent the release of toxic particles in the open air. This gas treatment is a function distinct from that of the generation of electrical energy by the generators mentioned above.

One of the aims of the present invention consists in proposing a solution making it possible to improve the existing one, in particular by means of a combination of functions within the same set. The invention relates to a thermoelectric device comprising a plurality of thermoelectric modules, said modules each comprising at least one thermoelectric element capable of generating an electric current under the action of a temperature gradient exerted between two of its faces, in contact with each other. a cold source on the one hand, and a hot source on the other hand, said thermoelectric device further comprising a device for treating toxic components.

The device of the invention is a thermoelectric device which allows, on the one hand, the generation of an electric current from a temperature gradient and, on the other hand, the treatment of toxic components of a fluid participating in this generation of current.

Thus, the thermoelectric device of the invention has the advantage of improving the existing thermoelectric devices by proposing to combine, within a single set, two previously separate technical functions.

 According to a first possible embodiment, said device comprises:

 a body having a plurality of housings for receiving said modules, said body further defining a central cavity devoid of thermoelectric module.

 a catalytic substrate as a toxic component treatment device disposed within said cavity, said substrate being designed to provide catalytic conversion of toxic components of a first fluid.

 In this way, it is planned to perform the catalytic conversion of these toxic components within said thermoelectric device, in particular using said catalytic substrate.

According to various embodiments of the invention, which may be taken together or separately:

 said first fluid constitutes said hot source,

 said substrate comprises a plurality of pores loaded with chemical elements to ensure said catalytic conversion of toxic components of the first fluid,

 said chemical elements are molecules of rare metals,

 the body has a substantially cylindrical section, thus defining, on its periphery, a housing ring for said modules, and, giving to said central cavity a substantially cylindrical section,

the substrate is of substantially cylindrical section so as to occupy substantially all of said cavity,

 said substrate is a porous material cake,

 said substrate is made of ceramic material,

said modules are held in said housings by secondary exchange surfaces, called fins, the fins comprise a catalytic coating so as to participate in said catalytic conversion of toxic components of the first fluid.

The invention also relates, advantageously, to a thermoelectric generator comprising a thermoelectric device such as that described above.

According to various embodiments of the invention, which may be taken together or separately:

 the thermoelectric generator of the invention further comprises a flow control device,

 said flow control device is positioned, in the flow direction of the first fluid, downstream of said catalytic substrate,

said flow control device comprises a valve, said valve comprising a valve body and a valve, said valve being articulated with respect to the valve body and being able to occupy an open position and a closed position, said valve being configured to being positioned inside said generator so as to modulate the quantity of the first fluid flowing through it,

 the valve body of said control device coincides with the body of said thermoelectric device, thus defining a same central cavity, called generator duct,

 the thermoelectric generator of the invention is configured so that, when the valve is in the closed position, the first fluid flows through the housings of said thermoelectric device and, when the valve is in the open position, said first fluid circulates at through the generator duct,

- The thermoelectric generator of the invention is intended to be coated with a protective outer casing, said housing, so as to be positioned in a motor vehicle exhaust line so that the exhaust gas flowing in said line define said first fluid and / or in a motor vehicle recirculated exhaust gas circuit such that said recirculated exhaust gas flowing in said circuit defines said first fluid. According to a second possible embodiment, said device further comprises an electrode capable of being powered by a portion of the electric current generated by the at least one thermoelectric element, said electrode being intended, as a device for treating toxic components, electrically charging toxic particles of a first fluid to agglomerate said toxic particles together.

 In this embodiment, it is thus planned to agglomerate these toxic particles within said thermoelectric device, in particular by electrically charging said particles.

According to various embodiments of the invention, which may be taken together or separately:

 said first fluid constitutes said hot source,

 said cold source consists of ambient air,

 said electrode is disposed upstream of said generator,

 the electric generator comprises a plurality of thermoelectric elements capable of generating an electric current under the action of a temperature gradient exerted between two of their faces; said plurality of elements is in contact with the hot source via a first a plurality of thermally conductive fins,

 said fins are configured so as to retain on their surfaces the agglomerates of toxic particles,

 said fins are metallic,

 said thermoelectric elements are parallelepipedal elements,

 said plurality of elements is in contact with the cold source via a second plurality of heat-conducting fins, in particular metal fins,

the thermoelectric device of the invention is configured so that part of the electric current generated by the thermoelectric generator is able to supply, in addition, the charge of a capacitor,

- The thermoelectric device of the invention is intended to be coated with a protective outer casing, said housing, so as to be positioned in a motor vehicle exhaust line so that the exhaust gas flowing in said line defines said first fluid and / or in a recirculated exhaust gas system of a motor vehicle so that said recirculated exhaust gas flowing in said circuit define said first fluid.

The invention will be better understood, and other objects, details, features and advantages thereof will become more clearly apparent in the following detailed explanatory description of at least one embodiment of the invention given to As a purely illustrative and non-limiting example, with reference to the accompanying schematic drawings.

 On these drawings:

 FIG. 1 schematically illustrates an example of the first possible embodiment of the invention, with a body of a thermoelectric device and a catalytic substrate, for cross-sectional view,

 FIG. 2 is substantially the same schematic illustration as in FIG. 1, the thermoelectric modules in addition,

 FIG. 3 schematically illustrates an exemplary embodiment of a thermoelectric generator according to the invention, with a view to longitudinal section,

 FIG. 4 is a graph illustrating an example of management of a flow control device of a thermoelectric generator according to the invention, and

 - Figure 5 is a schematic illustration of an embodiment of a thermoelectric device according to the second possible embodiment of the invention, said device being shown in the longitudinal direction.

As illustrated in FIG. 2, the invention relates to a thermoelectric device 10 comprising a plurality of thermoelectric modules 20, said modules 20 each comprising at least one thermoelectric element 22 capable of generating an electric current under the action of a temperature gradient exerted between two of its faces, in contact with a cold source F1 on the one hand, and a hot source F2 on the other hand (see Figure 3). FIG. 3 schematically illustrates, in effect, a thermoelectric generator 12 according to the invention, in in particular when it is positioned in a motor vehicle exhaust line and / or in a recirculated exhaust gas circuit of a motor vehicle. The exhaust gases of said motor vehicle are used, here, as hot source F2 to generate a temperature gradient with the cold source F1.

Said modules 20 comprise at least one thermoelectric element 22, here of annular shape. Assembled coaxially with each other, these thermoelectric elements 22 form the modules 20, otherwise called thermoelectric rods 20 (see FIG. 2). Said thermoelectric elements 22 and, subsequently, said thermoelectric rods 20 are capable of generating an electric current under the action of a temperature gradient. This is why the thermoelectric rods 20 comprise at their center tubes 24 in which circulates a coolant fluid which acts as a cold source F1.

 The thermoelectric modules 20 therefore comprise at least one thermoelectric element 22, here a plurality of thermoelectric elements 22 of annular shape, capable of generating an electric current under the action of a temperature gradient exerted between two of its faces, the one, said first face, being defined by an outer periphery surface, cylindrical, and the other, said second face, being defined by an inner periphery surface, cylindrical.

 Said first and second faces are, for example, oval section for the first and / or circular for the second. More generally, any section of rounded and / or polygonal shape is possible.

 Such elements 22 operate, according to the Seebeck effect, by making it possible to create an electric current in a load connected between said faces subjected to the temperature gradient. In a manner known to those skilled in the art, such elements 22 consist, for example, of Bismuth and Tellurium (Bi2Te3).

The thermoelectric elements 22 may be, for a first part, elements of a first type, called P, making it possible to establish an electric potential difference in a direction, called positive, when they are subjected to a given temperature gradient , and, for the other part, elements of a second type, called N, allowing the creation of an electrical potential difference in the opposite direction, called negative, when they are subjected to the same temperature gradient (see Figure 3). The thermoelectric elements 22 consist of a ring in one piece. They may however be formed of several pieces each forming an angular portion of the ring.

 The first surface has, for example, a radius between 1, 5 and 4 times the radius of the second surface. It could be a radius equal to about twice that of second surface.

 Said thermoelectric element 22 has, for example, two opposite parallel flat faces. In other words, the ring constituting the thermoelectric element 22 is of rectangular annular section.

The thermoelectric device 10 according to the invention comprises a body 30 having a plurality of housings 32 intended to receive said modules 20 (see FIGS. 1 and 2). Said body 30 further defines a central cavity 34 devoid of thermoelectric module 20. The term "central cavity" means a hollow zone, without material, within which a fluid can flow without obstacle.

According to the invention, said thermoelectric device 10 further comprises a catalytic substrate 40 disposed inside said cavity 34, said substrate 40 being designed so as to ensure a catalytic conversion of toxic components of a first fluid.

Here, said first fluid constitutes the hot source F2. In other words, in the context of the example illustrated here, the hot source F2 comes from the exhaust gases of said motor vehicle.

The function of the substrate 40 is to control the emission of the exhaust gas at the outlet of the motor vehicle.

 Said substrate 40 will advantageously be a roll of extruded material, more specifically a bread of porous material.

More specifically, said substrate 40 comprises a plurality of pores loaded with chemical elements, in particular to ensure said catalytic conversion of toxic components of the first fluid F2. Said chemical elements are molecules of rare metals, for example Platinum, Rhodium or Palladium molecules. Thus, said substrate 40 will advantageously be a porous material roll, made of ceramic material, or even of metallic material. Such a substrate 40 will be loaded with rare metal molecules by dipping into a bath comprising this type of rare metals, then by a step of vaporizing the assembly so that the rare metal molecules remain trapped in the pores of said substrate 40. Said molecules will be used for the catalytic reactions, in particular in contact with the exhaust gases constituting the hot source F2, said catalytic reactions allowing the depollution of said exhaust gases F2. As illustrated in Figures 1 and 2, the body 30 advantageously has a substantially cylindrical section, thereby defining, on its periphery, a housing ring 32 for said modules 20, and giving to said central cavity 34 a substantially cylindrical section. In other words, said body 30 is a hollow cylinder, which extends along a main direction of extension, said main direction and marked X in Figures 1 to 3, and whose wall is thick enough for housing 32, coaxial with said main direction X, are provided.

 The substrate 40 will advantageously have a shape enabling it to occupy substantially all of the cavity 34 of said body 30. Thus, in the example illustrated here, the substrate 40 has a substantially cylindrical section.

On the other hand said modules 20 are held in said housings 32 by secondary exchange surfaces, called fins 26 (see Figure 2). These fins 26 also allow the centering of said modules 20 in these housings 32. Said fins 26, for example obtained in metallic material, advantageously comprise a catalytic coating so as to participate in said catalytic conversion of toxic components of the first fluid F2.

The invention also relates, advantageously, to a thermoelectric generator 12 comprising a thermoelectric device 10 such as that described above. The thermoelectric generator of the invention 12 may furthermore comprise a flow control device 64 (see FIG. 3). As illustrated in FIG. 3, said flow control device 64 is positioned - in the direction of flow of the first fluid along the main direction X - downstream of said catalytic substrate 40.

 Said flow control device 64 has the function of modulating the flow rate of said exhaust gases, or hot source F2, through said generator 12. In other words, its function consists in directing the flow of the hot source F2 as close as possible to the thermoelectric elements 22, especially in case of low flow.

To do this, the flow control device comprises, advantageously, a valve 50. Said valve 50 comprises a valve body 52 and a valve 54. The valve body 52 comprises a central orifice, open or not, depending on the valve position 54. Indeed, the valve 54 is hinged relative to the valve body 52. The valve 30 is therefore able to occupy an open position, a closed position, or an intermediate position (see Figure 3). The control device 54 may comprise for this purpose actuating means of the shutter, not shown, for example integrated in the generator 12. They are advantageously configured to allow said shutter 54 to occupy any angular position.

 The course of said gases is shown schematically by arrows in Figure 3. The arrows represent a gas flow. Schematically, we represented a large flow by thicker arrows.

Advantageously, and particularly for reasons of integration and compactness of the generator 12, the valve body 52 of said control device 54 coincides with the body 30 of the thermoelectric device 10, thus defining a same central cavity 34, called the generator duct. 34. This duct 34 will be called, in the following, flow conduit. This duct 34 is particularly adapted to the flow of the exhaust gas F2.

Thus, when the valve 50 is open, the gases flow through the duct 34 and only a small fraction of said gases pass through the fins 26 of the modules 20. This case appears in particular when starting the heat engine (engine not illustrated). The temperature of the gases is then, for example, less than 400 ° C for a cooling fluid whose temperature is, for example, less than 100 ° C. It should be noted that the fraction of gases passing through the Generator 12 promotes the transfer of heat from the hot gases in the cold liquid during the engine start phases, which may allow to accelerate its temperature setting. On the other hand, when the valve 50 is in the closed position, the gases are guided towards the thermoelectric modules 20, as close as possible to the fins 26 of said modules 20. More specifically, a housing 60 is placed around the thermoelectric generator 12 for guide said gas to the modules 20. This configuration, illustrated in Figure 3, is more particularly suitable for low exhaust gas flow rates. Said flow rate will be, for example, less than 30 g / s for a gas temperature, for example less than 750 ° C.

In other words, the thermoelectric generator 12 is configured so that, when the valve 54 occupies the closed position, the first fluid F2 flows through the housings 32 of said thermoelectric device 10 and, when the valve 54 is in the open position, said first fluid F2 flows mainly through the conduit of the generator 12, although a portion of said fluid F2 can come into contact with the fins 26.

 This means that said first fluid F2 undergoes a catalytic treatment irrespective of the position of said valve 54. When the valve 54 occupies the closed position, said first fluid F2 is mainly cleaned in contact with the coating carried by the fins 26. When the valve 54 occupies the open position, said first fluid F2 is mainly cleaned by passing through said substrate 40. This clearance of the exhaust gas F2 is due to chemical reactions, when in contact with the coating of the fins 26 and / or with the molecules of rare metals trapped in the substrate 40. These chemical reactions being exothermic, they participate, locally, in the generation of thermoelectric energy due to the temperature gradient between the faces of said thermoelectric elements 22, in particular at the fins 26.

It should be noted that the housing 60 serves as a protective outer casing, in particular so as to allow the positioning of said generator 12 in a motor vehicle exhaust line and / or in a recirculated exhaust gas circuit of a motor vehicle. Therefore, the thermoelectric generator 12 of the invention, comprising said thermoelectric device 10 and said flow control device 54, acts as a thermoelectric energy generator and as a controller for the emission of toxic gases.

The operation of the flow control device 54 will be in relation to the measured exhaust gas flow rate F2, for example at the input of the thermoelectric generator 12:

 - when the flow is less than 20% of the maximum measurable flow, the valve

50 is closed and the exhaust gas passes exclusively in the vicinity of the modules 20, through the housings 32, via the fins 26 (see part A of the graph of Figure 4);

 when the flow rate is greater than 20% of the maximum measurable flow rate while remaining less than 100% of this maximum measurable flow rate, the valve 50 is partially open to avoid a rise in the resulting pressure at the level of the thermoelectric modules 20 (see Part B). graph of Figure 4);

 when the flow is equal to 100% of this maximum measurable flow rate, the valve 50 is open and the resulting pressure is the same at the level of the thermoelectric modules 20 as in the catalytic substrate 40.

The abscissa of the graph of FIG. 4 corresponds to the ratio "measured flow" on "maximum measurable flow" and the ordinate of the same graph corresponds to an image of the resultant pressure at the level of the thermoelectric modules 20.

It should be noted that the thermoelectric generator 1 2 is sized to operate optimally when the gas flow rate F 2 is substantially equal to 50% of the maximum measurable flow rate, the catalytic substrate 40 being sized for optimum operation when the gas flow F 2 is substantially greater than 30% of the maximum measurable flow. It should also be noted that variant embodiments are of course possible. In particular, in a further exemplary embodiment (not shown), such a substrate 40 may be configured to be positioned in a heat exchanger, while ignoring the thermoelectric modules inserted between the cooling fluid tubes and the fins.

As illustrated in FIG. 5, the invention relates to a thermoelectric device 10, comprising a thermoelectric generator 12 capable of generating an electric current under the action of a temperature gradient in contact with a cold source F1 on the one hand, and a hot source F2 on the other hand.

 FIG. 5 schematically illustrates, in effect, a thermoelectric generator 12, in particular when it is positioned in a motor vehicle exhaust line 14 and / or in a recirculated exhaust gas circuit of a motor vehicle. The exhaust gases of said motor vehicle are used, here, as hot source F2 to generate a temperature gradient with the cold source F1.

Said device 10 further comprises an electrode 70. The term "electrode" means an electrical means capable of electrostatically charging elementary particles, in particular nanoparticles.

According to the invention, said device 10 is configured so that a part of the electric current generated by the thermoelectric generator 10 is able to supply said electrode 70. This has the advantage of using locally the electrical energy generated by said generator 12.

Said electrode 70 is intended to electrically charge toxic particles of a first fluid so as to agglomerate said toxic particles together. Advantageously, said first fluid constitutes said hot source F2; in the example described here, said first fluid is formed by the exhaust gas.

On the other hand, said cold source F1 is constituted by ambient air. This has the advantage of avoiding any risk of local short circuit, risk existing when the cold source is, for example, in liquid form. Here, this ambient air comes from the air flowing under the floor of the car, especially because the exhaust line 14 is so designed that it is close to said floor. The ambient air may also come from a different place, for example from outside the passenger compartment of the car; it depends on the architecture chosen for said exhaust line.

It should be noted that the electric generator comprises a plurality of thermoelectric elements 22 capable of generating an electric current under the action of a temperature gradient exerted between two of their faces. The elements 22 are advantageously of parallelepipedal shape. This allows them optimal integration within the thermoelectric generator 12; this also allows an optimal contact with a first and a second plurality of thermally conductive fins 72, 74, also of parallelepipedal shape.

It should be noted that such elements 22 operate, according to the Seebeck effect, by making it possible to create an electric current in a load connected between said faces subjected to the temperature gradient. In a manner known to those skilled in the art, such elements 22 consist, for example, of Bismuth and Tellurium (Bi2Te3).

 The thermoelectric elements 22 may be, for a first part, elements of a first type, called P, making it possible to establish an electric potential difference in a direction, called positive, when they are subjected to a given temperature gradient , and, for the other part, elements of a second type, called N, allowing the creation of an electric potential difference in the opposite direction, called negative, when they are subjected to the same temperature gradient

Said thermoelectric elements 22 have, for example, two opposite parallel flat faces, a first in contact with the first plurality of fins 72 and an opposite second, in contact with the second plurality of fins 74. The first plurality of fins 72 is intended to facilitate heat transfer between the hot source F2, here the exhaust gas, and the thermoelectric elements 22, at least with the face which is in contact with said fins 72. These fins 72 are preferably provided metal. On the other hand, said fins 72 are configured to retain, on their surfaces, the agglomerates of toxic particles. In other words, the electrode 70, advantageously disposed upstream of the generator 12 in the direction of circulation of the exhaust gases, electrically charges these particles, which attract each other. They then form agglomerates of particles, agglomerates which are then retained on the surface of said fins 72. This makes it possible to clean up the exhaust gases by filtration.

Thus, the device of the invention uses the exhaust gas as hot source F2 for the thermoelectric generator 12, and at the same time, allows its depollution by filtering the toxic particles that it contains, this before its release out of the exhaust line 14 (reference F2 'in Figure 1).

 It should be noted that the flow direction is represented by arrows in FIG.

The regeneration of the thermoelectric generator 12 of the invention, consisting in cleaning the fins 72 of the particle agglomerates, in particular by pyrolysis, is initiated, locally, by an electric arc generated by a capacitor (not shown here). It should be noted that the charge of such a capacitor is advantageously provided by the thermoelectric device 10 of the invention.

 This contributes to the autonomy of the device 10 of the invention, which generates current, participates in the depollution of the exhaust gas that it uses as a hot source, and electrically supplies the elements for its own regeneration. Thus, the device of the invention acts as a filter for the exhaust gases, more precisely as a high voltage filter. This is why it is advantageous for said device to be as integrated and autonomous as possible, in particular since any high voltage in a motor vehicle must remain local.

 For example, the voltage generated here may be of the order of about 3000 volts.

On the other hand, a housing 80 will advantageously be placed around the thermoelectric generator 12 to guide the hot source F2. Said casing 80 will also serve as a protective outer casing, in particular so as to allow the positioning said generator 12 in the exhaust line 14 of the motor vehicle and / or in a recirculated exhaust gas circuit of the motor vehicle (circuit not shown here).

It should be noted that the plurality of thermoelectric elements 22 are in contact with the cold source, the ambient air, via the second plurality of thermally conductive fins 74. These fins 74 are preferably metallic. They will advantageously be mounted on the housing 80.

By way of example, the hot source F2 will have a temperature of several hundred degrees, for example about 700 ° C., whereas the cold source F1 will have a temperature of a few tens of degrees, while being less than about 60 ° C. ° C.

It should also be noted that variant embodiments are of course possible. In particular, in a further embodiment (not shown), such a depollution electrode 70 is configured to be positioned in a heat exchanger, this ignoring the thermoelectric elements inserted here in the housing.

Claims

claims

1. A thermoelectric device (10) comprising a plurality of thermoelectric modules (20), said modules (20) each comprising at least one thermoelectric element (22) capable of generating an electric current under the action of a temperature gradient exerted between two of its faces, in contact with a cold source (F1) on the one hand, and a hot source (F2) on the other hand, said thermoelectric device further comprising a device for treating toxic components.

2. thermoelectric device (10) according to the preceding claim, comprising a body (30) having a plurality of housings (32) for receiving said modules (20), said body (30) further defining a central cavity (34) devoid thermoelectric module, said thermoelectric device (10) further comprising, as a device for treating toxic components, a catalytic substrate (40) disposed within said cavity (34), said substrate (40) being designed in order to ensure a catalytic conversion of toxic components of a first fluid.

3. thermoelectric device (10) according to the preceding claim, wherein said first fluid (F2) constitutes said hot source.

The thermoelectric device (10) according to any one of claims 2 or 3, wherein said substrate (40) comprises a plurality of chemically charged pores for providing said catalytic conversion of toxic components of the first fluid (F2).

5. thermoelectric device (10) according to the preceding claim, wherein said chemical elements are molecules of rare metals.

6. thermoelectric device (10) according to any one of claims 2 to 5, wherein the body (30) has a substantially cylindrical section, thereby defining, on its periphery, a housing ring (32) for said modules (20), and giving said central cavity (34) a substantially cylindrical section.

7. Thermoelectric device (10) according to the preceding claim, wherein the substrate (40) is of substantially cylindrical section so as to occupy substantially all of said cavity (34).

Thermoelectric device (10) according to one of claims 2 to

7, wherein said substrate (40) is a porous material roll.

Thermoelectric device (10) according to one of claims 2 to

8, wherein said substrate (40) is made of ceramic material.

Thermoelectric device (10) according to one of claims 2 to

9, wherein said modules (20) are held in said housings (32) by secondary exchange surfaces, called fins (26), the fins (26) comprising a catalytic coating so as to participate in said catalytic conversion of components toxic of the first fluid (F2).

1 1. A thermoelectric device (10) according to claim 1, said device further comprising an electrode (70) adapted to be powered by a portion of the electric current generated by the at least one thermoelectric element (22), said electrode (70) being intended , as a device for treating toxic components, to electrically charge toxic particles of a first fluid so as to agglomerate said toxic particles together.

12. Thermoelectric device (10) according to the preceding claim, wherein said first fluid constitutes said hot source (F2).

13. Thermoelectric device (10) according to any one of claims 1 1 or 12, wherein said cold source (F1) is constituted by ambient air.

Thermoelectric device (10) according to any one of claims 1 1 to 13, wherein said electrode (70) is disposed upstream of the thermoelectric modules (20).

The thermoelectric device (10) according to any one of claims 1 to 14, wherein said plurality of thermoelectric elements (22) are in contact with the hot source via a first plurality of thermally conductive fins (72). .

6. Thermoelectric device (10) according to the preceding claim, wherein said fins (72) are configured to retain, on their surfaces, agglomerates of toxic particles.

17. thermoelectric device (10) according to the preceding claim, wherein said fins (72) are metallic.

18. A thermoelectric device (10) according to any one of claims 1 1 to 17, wherein said thermoelectric elements (22) are parallelepiped elements.

19. A thermoelectric device (10) according to any one of claims 1 1 to 18, wherein said plurality of elements (22) is in contact with the cold source (F1) via a second plurality of fins (74) thermo -conductrices.

20. Thermoelectric device (10) according to any one of claims 1 1 to 19, configured so that a portion of the electric current generated by the at least one thermoelectric element (22) is able to supply, furthermore , the charge of a capacitor.

21. Thermoelectric device (10) according to any one of claims 1 1 to 20, intended to be coated with a protective outer casing, said housing (80), so as to be positioned in a vehicle exhaust line (14) automobile so that the exhaust gases flowing in said line (14) define said first fluid and / or in a gas circuit recirculated exhaust of a motor vehicle so that said recirculated exhaust gas flowing in said circuit define said first fluid.

22. thermoelectric generator (12), characterized in that it comprises a thermoelectric device (10) according to any one of claims 1 to 10.

23. thermoelectric generator (12) according to the preceding claim, characterized in that it further comprises a flow control device (64), said flow control device (64) being positioned in the direction of flow of the first fluid (F2), downstream of said catalytic substrate (40).

Thermoelectric generator (12) according to the preceding claim, wherein said flow control device (54) comprises a valve (50), said valve (50) comprising a valve body (52) and a valve (54), said valve (54) being articulated with respect to the valve body (52) and being able to occupy an open position and a closed position, said valve (50) being configured to be positioned inside said generator (12) so as to modulating the amount of the first fluid (F2) flowing through it.

25. thermoelectric generator (12) according to the preceding claim, wherein the valve body (52) of said control device is merged with the body (30) of said thermoelectric device (10), thereby defining a same central cavity (34), said conduit of the generator (34).

26. thermoelectric generator (12) according to the preceding claim, configured so that, when the valve (54) occupies the closed position, the first fluid (F2) flows through the housings (32) of said thermoelectric device (10). and when the valve (54) is in the open position, said first fluid (F2) flows through the generator duct (34).

27. thermoelectric generator (12) according to any one of claims 22 to 26, intended to be coated with a protective outer casing, said housing (60), so as to be positioned in a motor vehicle exhaust line so that the exhaust gas flowing in said line defines said first fluid and / or in a recirculated vehicle exhaust gas circuit. whereby said recirculated exhaust gas flowing in said circuit defines said first fluid (F2).