EP3844833A1

EP3844833A1 - Electrochemical device comprising an electrochemical unit disposed in a containment enclosure

Info

Publication number: EP3844833A1
Application number: EP19813626.9A
Authority: EP
Inventors: Michel Planque; Charlotte Bernard; Guilhem Roux
Original assignee: Commissariat a lEnergie Atomique CEA; Commissariat a lEnergie Atomique et aux Energies Alternatives CEA
Current assignee: Commissariat a lEnergie Atomique et aux Energies Alternatives CEA
Priority date: 2018-10-26
Filing date: 2019-10-22
Publication date: 2021-07-07
Also published as: FR3087953A1; WO2020084249A1; FR3087953B1; CA3116965A1; US20210344022A1; JP2022505580A

Abstract

The invention relates to an electrochemical device comprising: - an electrochemical unit (100) comprising: - a stack (200) of SOEC/SOFC-type solid oxides operating at high temperatures, - a clamping system provided with two clamping plates, referred to as the first clamping plate (300) and second clamping plate (310), respectively, between which the stack (200) is clamped, one and/or both of the two clamping plates having at least one gas inlet and at least one gas outlet; - heating means (340) which are designed to ensure the heating of the electrochemical unit (100) and are integrated into said unit (100); - a containment box (500), housed in a volume, referred to as internal volume V, the electrochemical unit (100), the internal volume V being delimited by a surface, referred to as the internal surface S, of the containment box (500), which follows the shape of the electrochemical assembly (100).

Description

TITLE

ELECTROCHEMICAL DEVICE COMPRISING AN ELECTROCHEMICAL ASSEMBLY ARRANGED IN A CONTAINMENT ENCLOSURE

DESCRIPTION

TECHNICAL AREA

The present invention relates to the general field of electrochemical devices provided with solid oxide electrochemical cells operating at high temperature.

The present invention relates in particular to an electrochemical device comprising a plurality of electrochemical cells sandwiched between two clamping plates.

The assembly formed by the electrochemical cells and the clamping plates also includes an integrated heating system as well as arrangements intended to improve its energy performance and in particular its thermal performance.

The device according to the present invention can in particular be used for high temperature electrolysis or as a fuel cell.

PRIOR STATE OF THE ART

FIG. 1 represents an electrochemical device known from the state of the art and described in the document [1] cited at the end of the description.

The electrochemical device comprises a stack of solid oxides operating at high temperature enclosed in two clamping plates which can operate either in the electrolyser mode or in the fuel cell mode.

The electrochemical device 10 is generally designated under one or the other of the acronyms "SOEC"("Solid Oxide Electrolyser Cell") or "SOFC"("Solid Oxide Full Cell") that it operates, respectively, in electrolyser mode or in fuel cell mode. The solid oxide stack operating at high temperature, as illustrated in FIG. 2, comprises a stack 200 of elementary electrochemical cells 210 between which are interposed interconnectors 230 intended to ensure electrical contact between the elementary electrochemical cells and also their distribution in reactive gases.

Each elementary electrochemical cell comprises an electrolyte 210e interposed between an anode 210a and a cathode 210c.

Throughout the description of the present application, by “anode”, “cathode” and “electrolyte”, we mean elements of generally planar shape, for example in the form of a layer, which comprise two main faces which are essentially parallel and connected by an outline.

The anode and the cathode of each elementary electrochemical cell generally comprise a porous layer, while the electrolyte forms a dense and tight layer.

Each interconnector disposed on either side of an electrochemical cell forms, respectively, with the anode an anode compartment 230a for distribution and collection of gas, and with the cathode a cathode compartment 230c for distribution and collection of gas.

In operation, the anode and the cathode are the seat of electrochemical reactions, while the electrolyte allows the transport of ions from the cathode to the anode, or vice versa depending on whether the electrochemical device operates in electrolyser mode or in battery mode fuel.

Thus in electrolyser mode, the cathode compartment allows a supply of water vapor and an evacuation of water reduction products, in particular hydrogen, while the anode compartment ensures, via a draining gas, the evacuation of the dioxygen produces oxidation of O ² ions migrating from the cathode to the anode.

The electrolysis mechanism (“SOEC” mode) of water vapor by an elementary electrochemical cell is illustrated in FIG. 3. During this electrolysis, the elementary electrochemical cell is supplied by a current flowing from the cathode to the anode. The water vapor distributed by the cathode compartment is then reduced under the effect of the current according to the following half-reaction:

2 H ₂ 0 + 4 e -> 2 H ₂ + 2 O ² .

The dihydrogen produced during this reaction is then removed, while the O ² ions produced during this reduction migrate from the cathode to the anode, via the electrolyte, where they are oxidized to dioxygen according to the half-reaction:

2 O ² -> 0 ₂ + 4 e.

The dioxygen thus formed is evacuated by the draining gas circulating in the anode compartment.

The electrolysis of water vapor responds to the following reaction:

2 H2O -> 2 H2 + 0 ₂ .

In fuel cell mode (“SOFC”), air is injected into the cathode compartment which dissociates into O ² ions. These migrate to the anode and react with dihydrogen flowing in the anode compartment to form water.

Operation in fuel cell mode allows the production of an electric current.

Optimizing the operation of such an electrochemical device known from the state of the art may however require certain constraints.

In particular, it is necessary to have electrical insulation between two successive interconnectors on pain of short-circuiting the elementary electrochemical cell, but also a good electrical contact and a sufficient contact surface between an elementary electrochemical cell and an interconnector. The lowest possible ohmic resistance is then sought between cells and interconnectors. This depends on the facing materials but also on the level of tightness of the stack.

In addition, it is necessary to have a seal between the anode and cathode compartments under penalty of having a recombination of the gases produced, leading to a reduction in yield and above all the appearance of hot spots. damaging the stack. Again, this seal depends on the design of the seals and the materials used, but also on the level of tightness of the stack.

Finally, it is preferable to have a good distribution of the gases both at the inlet and at the recovery of the products under penalty of loss of yield, inhomogeneity of pressure and temperature within the various elementary patterns, or even prohibitive degradations of the electrochemical cells.

Furthermore, in practice such a device is arranged in the enclosure of an oven 50 so as to maintain the latter at a temperature of 600 ° C. and 1000 ° C., in particular 800 ° C. The oven is for example a high power oven provided with heating elements 51 fixed to the outside of the electrochemical device. This configuration does not make it possible to regulate and uniformly distribute the thermal energy within said device.

In particular, strong temperature gradients can be observed both in the electrochemical device but also in the oven enclosure.

In operation, non-uniform heating inevitably induces a loss of efficiency of the electrochemical device, and is also a source of thermal stresses liable to damage the latter.

In addition, it is notable that an injection of the gases at high temperature, in particular between 600 ° C. and 1000 ° C., both in electrolysis mode and in fuel cell mode, has a certain advantage.

The gases entering and leaving the SOEC or SOFC high-oxide solid oxide stack can be heated prior to their injection into said stack, in particular with an oven as shown in FIG. 5.

In this regard, the furnace 20 comprises cold parts PF and hot parts PC, the latter comprising the hearth of the furnace 11, a looped tube 12 for managing the gas inlets and outlets of the electrochemical device.

There are then two main techniques for overheating the inlet gases in a high temperature electrolysis (SOEC) or fuel cell (SOFC) stack. As shown schematically in Figure 5, it is possible to have a loop tube 12 wound at the right of the heating resistors of the oven 20 in its hot part PC.

The gases are then previously heated to a temperature in the region of approximately 500 ° C. at the outlet of the exchangers, and then circulate in the loop tube 12 in order to be exposed to the radiation of the heating resistors. As a result of this exposure to radiation, the gases overheat at a temperature of approximately 300 ° C. before the latter are injected into the solid oxide stack.

Alternatively, it is possible to pass the gases through an electric heater 30 (FIG. 6) which comprises an inertial mass 31 of steel, a heating resistor 32 and a gas line tube 33 wound on the inertial mass 31. A such an electric heater 30 makes it possible to bring the incoming gases GE from 20 ° C. to a temperature of around 800 ° C. before their introduction (introduction outgoing gases GS) into the solid oxide stack.

However, these two techniques require the temperature of the gases to be adjusted very precisely in order to ensure the proper functioning of the electrochemical device.

Furthermore, the implementation of overheating according to the principle set out in Figure 5 requires the use of a complicated assembly due to the presence of windings, and in particular bending of the tubes in loops. The looped tubes increase the volume of the device accordingly, and also generate difficulties with regard to the overall assembly of the device (passage of the current leads, thermocouples, etc.).

In addition, the looped tube may require an expensive and time-consuming treatment in order to avoid pollution due to its oxidation.

The technique used in FIG. 6, on the other hand, has a space requirement which is not compatible with the current trend of proposing increasingly compact systems.

An object of the present invention is then to provide an electrochemical device for which the heating of the electrochemical device has an improved uniformity compared to the devices known from the prior art. Another object of the present invention is to provide an electrochemical device for which the heating is better regulated than that of a device known from the state of the art.

STATEMENT OF THE INVENTION

The aims of the present invention are, at least in part, achieved by an electrochemical device comprising:

- an electrochemical assembly comprising:

- a stack of solid oxides of the SOEC / SOFC type operating at high temperature,

a clamping system provided with two said clamping plates, respectively, first clamping plate and second clamping plate between which the stack is clamped, one and / or the other of the two clamping plates comprises at least one gas inlet and at least one gas outlet;

gas distribution and evacuation means intended for the operation of the cooperating stack, respectively with the at least one gas inlet and the at least one gas outlet,

- Heating means configured to heat the electrochemical assembly and integrated into said assembly;

- a confinement box, accommodating in a volume, called internal volume V, the electrochemical assembly, the internal volume V being delimited by a surface, called internal surface S, of the confinement box, conforming to the shape of the electrochemical assembly , and at a distance D from said assembly greater than a predetermined distance Dp, the predetermined distance being adjusted so that in the event of a leak of dihydrogen in the space between the interior surface and the electrochemical assembly, the oxidation of said dihydrogen allows to keep an oxygen level higher than 15%, the containment box further comprising a thermal insulating material. The combination of the integrated heating means and an internal surface S conforming to the shape of the electrochemical assembly makes it possible to improve the thermal efficiency of the electrochemical device.

Indeed, the conformity of the internal surface S allows the latter to reflect more efficiently the heat emitted by the electrochemical assembly in the direction of said assembly, and consequently, also makes it possible to consider heating means of reduced power compared to to those traditionally used in this type of application.

Furthermore, this combination also contributes to homogenizing the temperature within the electrochemical assembly, and thus improving the efficiency of the latter.

According to one embodiment, the confinement box comprises a sole on which the electrochemical device rests, walls and a vault, the sole, the walls and the vault being held by removable fixing means making the confinement box removable .

According to one embodiment, the walls and the vault form two half-shells capable of pivoting about an axis, advantageously perpendicular to the floor, in order to allow the opening of the confinement box.

According to one embodiment, the confinement box comprises handling means, in particular a strapping provided with a handle.

According to one embodiment, the heating means are integrated into one and / or the other of the two clamping plates.

According to one embodiment, the heating means comprise a resistive filament.

According to one embodiment, the electrochemical assembly further comprises two end plates called, respectively, first end plate and second end plate, interposing, respectively, between the first clamping plate and the electrochemical stack, and between the second clamping plate and the electrochemical stack, each of the first and / or second end plate further comprising at least one cooperating gas circulation duct with the gas distribution or discharge conduit, the gas circulation conduit allowing the circulation of the gases from a first end to a second end before their transfer to the electrochemical assembly.

The gas circulation conduit thus makes it possible to overheat the gases by the radiative effect of the heat produced by the electrochemical assembly, and thus to improve the performance of the electrochemical device.

According to one embodiment, the gas circulation conduit comprises a groove formed at one of the faces of the first and / or of the second end plate, the groove having convolutions, advantageously, the groove forms a sinusoid .

According to one embodiment, the clamping system further comprises at least two tie rods extending from one to the other of the two clamping plates and passing through orifices called clamping orifices made in each of the plates, the at least two tie rods with clamping means, in particular bolts, to allow the assembly of the two clamping plates together.

According to one embodiment, the at least two tie rods comprise hollow tubes and cooperate with the gas distribution and / or evacuation means, so as to allow the circulation of said gases from one end of a tube to the other end of said tube.

According to one mode of implementation, the device further comprises a sealed coupling system at high temperature of the stack for the supply and the outlet of gas, the coupling system comprises:

- A manifold, comprising at least two collection conduits for the supply and the outlet of gas, each provided with a collection orifice positioned opposite, respectively, the at least one gas inlet and the at least one gas outlet,

- at least two seals each placed between each collection orifice and the gas outlet or the gas inlet. BRIEF DESCRIPTION OF THE DRAWINGS

Other characteristics and advantages will appear in the following description of an electrochemical device, given by way of nonlimiting examples, with reference to the appended drawings in which:

- Figure 1 shows, in a perspective and partial view, an electrochemical device known from the prior art (Figure 3 of document [1]);

- Figure 2 is an exploded schematic view of a stack of two elementary electrochemical cells known from the state of the art and capable of being implemented in the context of the present invention;

- Figure 3 is a schematic view showing the principle of operation of an elementary electrochemical cell in high temperature solid oxide electrolyser (SOEC) mode;

- Figure 4 is a schematic view of an electrochemical device known from the state of the art disposed in an oven;

- Figure 5 illustrates the principle of the architecture of a furnace on which a high temperature electrolysis stack (SOEC) or fuel cell (SOFC) operating at high temperature is placed;

- Figure 6 illustrates the principle of an electric gas heater according to the prior art;

- Figure 7 is a schematic representation of a clamping plate provided with an integrated heating system according to the present invention, the integrated heating system shown in Figure 7 comprises in particular a resistive filament;

- Figures 8a and 8b are sectional views of the electrochemical device according to the present invention provided with the containment box, Figure 8a is in particular a view along a section plane perpendicular to a main face of a clamping plate and cutting l 'electrochemical assembly, Figure 8b is a view along a section plane parallel to a main face of a clamping plate and cutting said plate;

- Figure 9 is a schematic representation according to a perspective view of a confinement box provided with two half-shells; - Figure 10a is a schematic representation, in exploded view, of an electrochemical assembly provided with two end plates, and in particular two end plates each provided with a gas circulation duct;

- Figure 10b is a schematic representation, in perspective, of an end plate provided with a gas circulation duct;

- Figure 11 is a schematic representation of an electrochemical device provided with hollow tie rods and intended for the circulation of gas;

- Figure 12 is a schematic representation of an electrochemical device according to the present invention illustrating the coupling with a coupling system according to the present invention.

DETAILED PRESENTATION OF PARTICULAR EMBODIMENTS

The present invention relates to an electrochemical device 10 provided with an electrochemical assembly formed by an electrochemical solid oxide stack of SOEC / SOFC type sandwiched between two clamping plates and provided with an integrated heating system.

By “clamping plate” is meant a plate of generally planar shape, which comprises two main faces connected by a contour, and which when assembled in pairs are intended to maintain the cohesion of a stack of elementary electrochemical cells.

The device according to the present invention comprises a confinement enclosure whose internal volume houses the electrochemical assembly.

In this respect, the interior volume of the enclosure is delimited by an interior surface, conforming to the exterior shape, and at a distance D greater than a predetermined distance guaranteeing a minimum level of oxygen in the event of leakage of dihydrogen.

The combined implementation of the containment and the integrated heating system makes it possible to limit the radiative losses to the outside during the operation of the electrochemical device according to the present invention. Furthermore, the confinement enclosure allows better control of the heating imposed on the stack when it is in operation.

The invention is now described in relation to Figures 1 to 12.

The electrochemical device 10 according to the present invention is intended to be used for high temperature electrolysis ("SOEC" mode) or as a fuel cell ("SOFC" mode).

The electrochemical device 10 comprises an electrochemical assembly 100.

The electrochemical assembly 100 is provided with a stack 200 of solid oxides of the SOEC / SOFC type operating at high temperature (FIGS. 1 and 2);

The stack 200 notably comprises a plurality of elementary electrochemical cells 210 each formed, and in order, of a cathode 210c, an electrolyte 210e, and an anode 210a.

It is understood, without it being necessary to specify that “the cathode”, “the anode” and “the electrolyte” are of generally planar shape, for example in the form of layers, and include two main faces which are essentially parallel and connected by an outline.

In other words, an elementary electrochemical cell 210 is an assembly of ceramic layers, in particular an anode, an electrolyte and a cathode. In this respect, the electrolyte comprises a solid and dense ion conducting layer, while the anode and the cathode are porous layers.

The stack 200 may also include intermediate interconnectors 230, each of the intermediate interconnectors 230 being interposed between two adjacent elementary electrochemical cells 210 (FIG. 2).

The intermediate interconnectors 230 provide an electrical connection between the cathode and the anode of two adjacent elementary electrochemical cells 210.

The intermediate interconnectors also delimit fluid compartments at the surface of the electrodes with which they are in contact. In particular, the face of an intermediate interconnector 230 in contact with an anode 210a of an elementary electrochemical cell 210 defines a compartment called anodic compartment 230a.

Equivalently, the face of an intermediate interconnector 230 in contact with a cathode 210c of an elementary electrochemical cell 210 defines a compartment called cathode compartment 230c.

Each of the anode 230a and cathode 230c compartments allows the circulation of gases, in particular for the distribution and collection of said gases.

More particularly, within the framework of an implementation of the electrolysis of water, the cathode compartment 230c ensures, at the level of the cathode, a distribution of water vapor and allows the evacuation of dihydrogen, while the anode compartment 230a ensures, at the level of the anode, the circulation of a draining gas and the evacuation of oxygen.

The electrochemical assembly 100 also comprises a clamping system provided with two clamping plates, called respectively, first clamping plate 300 and second clamping plate 310 (FIG. 1).

Each clamping plate comprises two main faces which are essentially parallel and connected by a contour.

In particular, the stack 200 is sandwiched between the two clamping plates 300, 310.

Means configured to mechanically hold the clamping plates together are also used. The means may in particular comprise tie rods 300t which extend from one to the other of the two clamping plates and pass through orifices called clamping orifices made in each of the plates.

The tie rods cooperate with clamping means, in particular bolts, to allow the assembly of the two clamping plates together. These clamping means are, in this regard, described in the document [1] cited at the end of the description.

The clamping plates can be made of refractory austenitic steel, in particular of the AISI 310 type. Alloy stainless steels are particularly advantageous because they have excellent resistance to high temperatures. These steels are in particular very resistant to creep and deformation, and resist environmental attack.

The clamping plates 300, 310 may each have a thickness of between 20 and 30 mm, in particular of the order of 25 mm.

The clamping plates may include at least one EG gas inlet, and / or at least one SG gas outlet. These gas inlets and outlets are for example through holes formed in the clamping plate (s).

The electrochemical assembly also includes means for distributing and / or discharging gas 330 intended for the operation of the stack (FIG. 10a).

The gas distribution and evacuation means 330 comprise in particular a duct system allowing the circulation of gas, and more generally fluids, and their distribution and / or evacuation at the level of the anodes and cathodes of elementary electrochemical cells.

The gas distribution and evacuation means 330 may in particular comprise hollow tubes, partially passing through the electrochemical assembly from the at least one gas inlet EG and / or from the at least one gas outlet SG . These hollow tubes also include lateral openings communicating with the anode or cathode compartments so as to ensure the distribution and / or evacuation of gases at the level of said compartments.

The electrochemical assembly according to the present invention also comprises heating means 340 configured to heat the electrochemical assembly (FIGS. 7, 8a and 10a).

The heating means 340 are integrated into the electrochemical assembly.

By "integrated into the electrochemical assembly" is meant heating means arranged in the interior volume of the electrochemical assembly.

The heating means 340 may in particular comprise a resistive filament disposed on one of the main faces, preferably an inner face, of one and / or the other of the first and of the second clamping plate (FIG. 7). The resistive filament of FIG. 7 represents a coil, however any other pattern can be envisaged.

The electrochemical device 10 also includes a confinement box 500 which houses in its volume V, called internal volume V, the electrochemical assembly (FIGS. 8a, 8b and 9).

In particular, the volume V is delimited by a surface S, called the internal surface S, essentially conforming to the shape of the electrochemical assembly.

By “conforming to the shape of the electrochemical assembly”, is meant the same shape without however limiting the dimensions of the internal surface to those of the electrochemical assembly. In other words, the internal surface S follows the shape of the electrochemical assembly.

It is understood without it being necessary to specify that the confinement box is a closed enclosure.

Furthermore, the internal surface of S is at distance D from the electrochemical assembly, in particular the distance D can be greater than a predetermined distance Dp

The predetermined distance Dp is adjusted so that in the event of a leak of dihydrogen in the space between the interior surface and the electrochemical assembly, known as free space, the oxidation of said dihydrogen makes it possible to maintain a higher or equal oxygen level. at 15%.

This predetermined distance Dp, which is a function of the capacity of the stack to produce dihydrogen, can be determined by techniques known to those skilled in the art, and is therefore not detailed in the present invention.

For example, the distance D can be less than 10 mm, advantageously between 5 mm and 10 mm.

The free space can also house sensors, such as temperature sensors, hydrogen sensors, pressure sensors, or even current leads. The containment box 500 can include a bottom 500s on which the electrochemical device 10 rests, walls 500m and an arch 500v.

The floor, the walls and the vault can be maintained by removable fixing means making the containment box removable.

In a complementary or alternative manner, the walls and the vault form two half-shells 500cl and 500c2 capable of pivoting about an axis, advantageously perpendicular to the floor, in order to allow the opening of the confinement box (FIG. 9).

Still in a complementary or alternative manner, the confinement box comprises handling means, in particular a strapping provided with a handle.

The combination of a confinement box and integrated heating means according to the terms of the present invention makes it possible to reduce heat losses to the outside, and consequently to limit the thermal power of heating means necessary for proper functioning. of the electrochemical device.

The inventors have noticed that this reduction in heat losses is essentially due to the conformity of the internal surface S with the shape of the electrochemical assembly.

Furthermore, the integration of the heating means into the electrochemical assembly makes it possible to ensure better uniformity of heating of said assembly.

The containment box includes a thermal insulating material.

By “thermal insulating material” is meant a material which is suitable for limiting energy losses, and in particular thermal losses. Such a material within the meaning of the present invention has a thickness and a thermal conductivity adapted so that the product of these two physical quantities allows a limitation of the thermal losses of the amount of heat actually produced by the electrochemical assembly to 30%.

For example, the realization of losses equivalent to exothermicity

(physical or chemical processes producing heat) produced by the whole electrochemical may require that said losses are equal to the sum of all the losses, namely the losses at the level of insulators, the losses at the level of the ducts and / or overheating members, as well as the gas losses. In other words, the exotherm is roughly equal to 30% = Gas losses + Exchanger losses + Insulation losses

By way of example, the following table gives the thermal conductivities of different materials, in different temperature ranges, which may be suitable for their implementation in the context of the present invention:

In practice, a person skilled in the art will be able to choose the material having the lowest thermal conductivity, in particular in the range of working temperatures of the electrochemical device. In fact, the lower the thermal conductivity, the more the material is heat insulating.

As an example of thermal insulators, it can be envisaged to use at least one of the materials comprising alkaline earth silicate wools (“AES” or “Alkaline and Alkaline Earth Silicate” according to Anglo-Saxon terminology ).

Good confinement can be ensured by a confinement box having a thickness of between 200 mm and 300 mm.

Generally, for the choice of a high temperature insulation, the following characteristics can be considered to choose the high temperature insulation:

- the maximum, minimum, peak and continuous temperatures to which the insulation will be subjected; - the mechanical stresses (compression, vibration, ...) to which the insulation will be subjected;

- the chemical constraints to which the insulation will be subjected;

- the type of environment in which the insulation is found;

- Geometry, tolerances, plans of the containment box.

The material forming the confinement box can also be adapted to limit the diffusion of water vapor. In particular, the material may have a thickness and a coefficient of diffusion of water vapor adapted so that the product of these two quantities makes it possible to limit the diffusion of water vapor.

It is also possible to envisage implementing a water vapor diffusion barrier.

This barrier may include a first ceramic enclosure, for example of alumina, and with a thickness of between 0.25 mm and 2 mm, for example disposed between the confinement box and the electrochemical assembly. This first box would have the following properties:

- a non-porous barrier;

- resistant to high temperatures;

- very good resistance to corrosion, mechanical abrasion and wear;

- a relatively lightness;

- extreme hardness;

- low thermal capacity;

- high mechanical resistance;

- great flexibility of thin substrates.

An alternative solution could consist in coating the interior surface of the confinement box with alumina in liquid form (called ceramic mortar, or ceramic molding or coating).

This solution is particularly advantageous since it allows the covering of complex shapes such as the internal surface of the confinement. The covering of said surface can be carried out by means of a brush or a spatula. Such a coating can dry in ambient air or in an oven.

These solutions thus provide a composite insulator composed of a thick layer to produce the thermal barrier, and a thinner layer to limit the diffusion of water vapor.

By way of example, the following table lists the resistances to the diffusion of water vapor from a few materials which may be suitable for their use in the context of the present invention:

It is also understood, without it being necessary to specify it, that the material forming the confinement box has a thermal resistance allowing it to limit any degradation of said box when it is subjected to high temperatures and in particular the operating temperatures. of the electrochemical assembly.

Among the materials likely to be suitable, alkaline earth silicate wool (or “AES”) seems to be the materials of choice.

The electrochemical assembly can also include end plates, called, respectively, first end plate 240a and second end plate 240b arranged on either side of the stack 100 (FIGS. 1, 8a and 10a). In particular, the first end plate 240a and the second end plate 240b, are interposed, respectively, between the first clamping plate and the electrochemical stack, and between the second clamping plate and the electrochemical stack.

Each of the first and / or second end plate may comprise at least one gas circulation conduit 241 cooperating with the gas distribution or evacuation conduit, the gas circulation conduit allowing the circulation of gases from a first end to a second end before their transfer to the electrochemical assembly (Figures 8a, 10a and 10b).

The gas circulation duct 241 comprises a groove formed at one of the faces of the first and / or of the second end plate, the groove having convolutions, advantageously, the groove forms a sinusoid.

Such a configuration makes it possible to overheat the gases before their distribution at the cathodes and anodes of the various elementary electrochemical cells.

Indeed, in operation the electrochemical device, and in particular the elementary electrochemical cells produce heat capable of radiating in the direction of the end plates. Such radiated thermal energy can then advantageously participate in the overheating of the gases circulating in the gas circulation duct.

Such an overheating system essentially takes up the characteristics of the overheating system presented in the French patent application [2] is cited at the end of the description and is referenced by its filing number. This document [2] is, in this regard, incorporated by reference into the present application.

Complementarily or alternatively to the gas circulation conduit described above, the electrochemical device can also include a gas conduit formed by the tie rods 300t. In particular, the tie rods may comprise hollow tubes cooperating with the gas distribution and evacuation means so as to allow the circulation of said gases from one end to the other end of said tube (FIG. 11). Thus, a gas circulating in the tie rods, during an operating phase of the electrochemical device, can be heated, or even overheated, by radiation of the heat produced by the elementary electrochemical cells before being introduced into the distribution means and / or d gas evacuation.

It is possible to increase the heat exchange time between the gas flowing in a given tie rod, and the radiated thermal energy, by positioning baffles on the internal surface of said tie rods.

Such an overheating system essentially takes up the characteristics of the overheating system presented in the French patent application [3] is cited at the end of the description and is referenced by its filing number. This document [3] is, in this regard, incorporated by reference into the present application.

The device can also comprise a tight coupling system at high temperature of the stack for the supply and the outlet of gas, the coupling system 30 comprises (FIG. 12):

- A manifold 31 which comprising at least two collection conduits for the supply and the gas outlet each provided with a collection orifice 33 positioned opposite, respectively, of the at least one gas inlet EG and at least one gas outlet (SG),

- At least two seals 35 each placed between each collection orifice 33 and the gas outlet or the gas inlet.

Such a sealed coupling system essentially takes up the characteristics of the sealed coupling system presented in the French patent application [4] is cited at the end of the description and is referenced by its filing number. This document [4] is, in this regard, incorporated by reference into the present application.

This coupling system allows rapid coupling between the electrochemical device and a gas supply. The coupling is established in particular at one of the clamping plates.

The proposed arrangements of the electrochemical device according to the terms of the present invention can be considered individually or collectively. The consideration of a containment and an integrated heating system allows the production of a compact electrochemical device and having improved thermal efficiency compared to the devices known from the prior art.

Furthermore, the confinement enclosure can be adapted to allow stacking, or the integration of several electrochemical devices in the form of a “rack”.

REFERENCES

[1] FR 3,045,215;

[2] FR 1760114;

[3] FR 1760106;

[4] FR 1762507.

Claims

1. Electrochemical device (10) comprising:

- an electrochemical assembly (100) comprising:

- a stack (200) of solid oxides of the SOEC / SOFC type operating at high temperature,

- a clamping system provided with two clamping plates called, respectively, first clamping plate (300) and second clamping plate (310) between which the stack (200) is enclosed, one and / or the other of the two clamping plates comprises at least one gas inlet (EG) and at least one gas outlet (SG);

- gas distribution and evacuation means (330) intended for the operation of the stack (200) cooperating, respectively with the at least one gas inlet (EG) and the at least one gas outlet (SG ),

- heating means (340) configured to heat the electrochemical assembly (100) and integrated into said assembly (100);

a containment box (500), accommodating in a volume, called the internal volume V, the electrochemical assembly (100), the internal volume V being delimited by a surface, called the internal surface S, of the containment box (500), conforms to the shape of the electrochemical assembly (100).

2. Device according to claim 1, in which the confinement box (500) comprises a sole (500s) on which the electrochemical device rests, walls (500m) and an arch (500v), the sole (500s), the walls (500m) and the vault (500v) being held by removable fixing means making the containment box (500) removable.

3. Device according to claim 2, wherein the walls (500m) and the vault (500v) form two half-shells (500cl, 500c2) capable of pivoting about an axis, advantageously perpendicular to the floor (500s), so to allow the opening of the containment box (500).

4. Device according to one of claims 1 to 3, wherein the containment box (500) comprises handling means, in particular a strapping provided with a handle.

5. Device according to one of claims 1 to 4, wherein the heating means (340) are integrated into one and / or the other of the two clamping plates.

6. Device according to one of claims 1 to 5, wherein the heating means (340) comprise a resistive filament.

7. Device according to one of claims 1 to 6, in which the electrochemical assembly (100) further comprises two end plates said to be, respectively, first end plate (240a) and second end plate (240b), interposed, respectively, between the first clamping plate (300) and the electrochemical stack (200), and between the second clamping plate (310) and the electrochemical stack (200), each of the first (240a) and / or second plate terminal (240b) further comprising at least one gas circulation conduit cooperating with the gas distribution or evacuation conduit, the gas circulation conduit allowing the circulation of gases from a first end to a second end before their transfer to the electrochemical assembly (100).

8. Device according to claim 7, in which the gas circulation duct (241) comprises a groove formed at one of the faces of the first (240a) and / or of the second (240b) end plate, the groove having convolutions, advantageously, the groove forms a sinusoid.

9. Device according to one of claims 1 to 8, wherein the clamping system further comprises at least two tie rods (300t) extending from one to the other of the two clamping plates and passing through said orifices clamping holes made in each of the plates, the at least two tie rods (300t) with clamping means, in particular bolts, to allow the assembly of the two clamping plates together.

10. Device according to claim 9, which the at least two tie rods

(300t) comprise hollow tubes and cooperate with the gas distribution and / or evacuation means, so as to allow the circulation of said gases from one end of a tube to the other end of said tube.

11. Device according to one of claims 1 to 10, wherein the device further comprises a tight coupling system at high temperature of the stack (200) for the supply and outlet of gas (SG), the system coupling (30) comprises:

- A manifold (31), comprising at least two collection conduits for the gas supply and outlet (SG) each provided with a collection orifice (33) positioned opposite, respectively, the at least one gas inlet (EG) and at least one gas outlet (SG),

- at least two seals (35) each placed between each collection orifice (33) and the gas outlet (SG) or the gas inlet (EG).