DE19515457C1 - High temp. fuel cell - Google Patents

Abstract

The fuel cell has an electrolyte matrix (1) containing the electrolyte with an anode (4) and a cathode (5) on opposite sides and sealing rails (2,3) around the outside of the fuel cell for sealing the anode and cathode gas spaces. A sealing element (1A) of the electrolyte matrix fits between the sealing rails and is provided by a sealing material contained within the electrolyte which remains solid at the operating temp. of the fuel cell, e.g. K2CO3 or LiCO3.

Description

The invention relates to a fuel cell. In particular, the invention relates to a Fuel cell with an electrolyte matrix containing an electrolyte, one on one Side of the electrolyte matrix arranged anode and one on the opposite side the electrolyte matrix arranged cathode, as well as with the gas space of the anode and Sealing strips and a cathode in the edge region of the fuel cell sealing element of the electrolyte matrix extending between the sealing strips for sealing their edge area.

In the case of a fuel cell, in particular in a molten carbonate fuel cell, there is one Electrolyte matrix embedded between an anode and a cathode. The Electrolyte matrix consists of an embedded in a matrix material Melt electrolyte, which usually consists of an alkali carbonate melt with the Components Li2CO3 and K2CO3 or / and Na2CO3 exists. The anode is usually made made of a porous nickel material, the cathode made of lithium doped Nickel oxide. A larger number of such cathode electrolyte matrix Fuel cell formed anode element are mutually separated by one so-called bipolar plate combined to form a fuel cell stack. The bipolar plates are used on the one hand for gas separation of the fuel gas or the gas spaces through which the anode and cathode flow simultaneous formation of corresponding flow cross sections on the surface of  Cathode and anode, and on the other hand for electrical contacting of the anode and Cathode with the help of current collectors contained in the bipolar plate. Through the Bipolar plates are the fuel cells in the fuel cell stack, electrically serial interconnected.

The gas spaces formed in the area of the anode and cathode of the fuel cells must both against each other within a fuel cell, d. H. Anode space against Cathode compartment, as well as gas-tight to the outside. The one for that The sealing materials used do not only have to protect against the gases used, namely the fuel gas and the cathode gas, i.e. one oxidizing and one reducing atmosphere, but also against that Melting electrolytes. Most currently in molten carbonate fuel cells The type of seal used is the so-called "wet seal", in which the existing cell electrolyte in a porous, usually elastic support structure as Sealing material is used. Preferably, that in the cell between the Electrodes arranged, the carrier material for the electrolyte forming electrolyte matrix extended laterally beyond the electrodes and in the edge area of the cell as Seal layer continued.

The advantage of this known solution is its manufacturing simplicity. Stand by but a number of disadvantages, namely electrolyte losses due to "creep" the electrolyte over the cell edge to the outside; incomplete electrical insulation of the two half cells against each other due to the residual conductivity of the seal; Corrosion of the Material parts due to the chemically aggressive melt electrolyte and electrochemical Corrosion processes; as well as mechanical weaknesses in the transition between that of area of the electrolyte matrix in the cell interior and the electrodes Border area of the cell.

DE 37 19 525 A1 describes a sealing material of high temperature and Corrosion resistance from an acid-resistant fluorinated elastomer demonstrated. The Sealing material is arranged in the fuel cell during assembly and expands when the cell heats up, causing irregularities in the Sealing edge course can be compensated.

In the molten carbonate fuel cell according to DE-OS 29 08 600 forms the Electrolyte matrix a wet seal. This acts against the electrodes  protruding edge of the electrolyte matrix together with sealing areas on housings that the Form gas spaces for the anode and cathode. To prevent corrosion of the contact points prevent, the surface of the metallic sealing areas is provided with aluminum.

In the fuel cell according to EP 0 560 731 A1, the type of seal is also one So-called wet seal, the electrolyte matrix protrudes beyond the electrodes and forms a sealing layer. To protect the electrode edges against oxidation the electrodes in the manufacture of the cell with high pressure against the electrolyte matrix pressed so that they sink into it and the electrolyte material wraps around the side edges of the Electrodes.

The object of the present invention is to provide a fuel cell in which the Edge seal is just as simple as the conventional wet seal, which, however, has greater mechanical and chemical stability.

This object is achieved according to the present invention in a fuel cell assumed type solved in that the sealing element of the electrolyte matrix by one chemically related to the electrolyte contained in the electrolyte matrix  fusible material is formed, which at the working temperature of the cell in is essentially firm.

A major advantage of this solution according to the invention is that Electrolyte losses due to the electrolyte "creeping" outwards through the cell edge is prevented, whereby a mechanically firm and gas-tight seal is ensured. Characterized in that a material chemically related to the electrolyte for the sealing interactions between the (solid) sealing material and the (molten) electrolyte are kept sufficiently low.

The sealing material preferably consists essentially of one of the components of the electrolyte consisting of a mixture, in particular of K2CO3 or Li2CO3 in the case of a melt electrolyte formed by these components. This will advantageously the manufacture of the cell is considerably simplified.

According to a development of the invention, the sealing material essentially consists from a mixture of the components of the electrolyte, this mixture being one higher melting point than the electrolyte mixture in the effective range of Has electrolyte matrix between anode and cathode. Mixing can be preferably again a mixture of K2CO3 and Li2CO3 in another Mix ratio act as in the effective area of the electrolyte matrix. Also this in turn considerably simplifies the manufacture of the cell.

Alternatively, the sealing material can be a glass or a vitreous substance contains at least one of the components of the electrolyte as a component of the mixture. This makes it possible to produce a chemically particularly stable seal that at the same time, however, it is chemically closely related to the electrolyte.

It can advantageously be provided that the sealing material in the Working temperature of the fuel cell is tough plastic. This makes a particularly good one Sealing reached.

According to an embodiment of the invention, it is provided that Matrix material of the electrolyte matrix itself in the edge area of the fuel cell with the Sealing material is impregnated gastight. The seal is thus in one piece with the  Electrolyte matrix formed, which is special for the simplification of manufacture Advantage is.

Alternatively, the seal can be separated from the electrolyte matrix Sealing strip can be formed, which is impregnated with the sealing material There is matrix material. The advantage of this is that the sealing strip and electrolyte matrix can be separated from each other and thus manufactured independently.

A further design simplification of the cell structure is obtained if the anode and / or cathode together with the electrolyte matrix 1 are guided into the edge area of the fuel cell and are impregnated with the sealing material in a gas-tight manner in the edge area of the fuel cell. As a result, it is advantageously possible to lead the electrodes and the electrolyte matrix as a package to the edge region of the fuel cell and thus seal them directly. In particular, there is no mechanical discontinuity which results in a weak point in the transition between the area of the electrolyte matrix encompassed by the electrodes and its edge area.

According to one aspect of the invention, the sealing material is at a higher temperature molten in the edge of the cell and is at working temperature the fuel cell solid or viscous.

Exemplary embodiments of the invention are described below with reference to the drawing explained. Show it:

Figure 1 in cross section a partial view of the edge of the fuel cell with a seal according to a first embodiment of the invention.

Figs. 2 and 3 in cross section a view of a part of the edge of the fuel cell with a gasket according to a second and a third embodiment of the invention;

Fig. 4 in cross section a view of part of the edge of a fuel cell with a seal according to the prior art.

Fig. 4 shows in cross section the edge of a fuel cell having a sealing of the gas spaces of anode and cathode according to the prior art.

An electrolyte matrix 1 , which is formed by a matrix material impregnated with a molten electrolyte, is arranged between an anode 4 and a cathode 5 , through which an anode-side gas space or a cathode-side gas space is formed. The gas spaces of the anode 4 and the cathode 5 are each sealed to the outside by sealing strips 2 , 3 in the edge region of the fuel cell. These sealing strips can be provided separately from the anode and cathode or can be part of the relevant electrode. In the type of sealing according to the prior art shown in FIG. 4, the melt electrolyte present in the cell is used in the electrolyte matrix as a so-called "wet seal", in that the electrolyte matrix extends laterally beyond the electrodes and in the edge region of the cell as a sealing layer is continued.

Fig. 1 shows a view in cross section of the cell edge of a fuel cell having a seal according to a first embodiment of the invention. Here, too, an electrolyte matrix 1 is embedded between an anode 4 and a cathode 5 , with respective anode-side and cathode-side gas spaces being formed by the anode and cathode. The gas spaces of the anode 4 and cathode 5 are in turn sealed off from the outside by sealing strips 2 and 3 in the edge region of the cell. Similar to the shown in Fig. Known type of seal 4, the electrolyte matrix is again extended beyond the anode 4 and cathode 5 side to the outside, however, the electrolyte matrix 1 in this a sealing member 1 A forming edge portion is impregnated with a material different from the material of the melt electrolyte is different within the effective range of the electrolyte matrix between anode 4 and cathode 5 , but is chemically related to them. This sealing material is a meltable material that is molten at elevated temperature in order to be able to soak the electrolyte matrix 1 , but at the working temperature of the fuel cell it is essentially solid, in contrast to what a solid or viscous or viscous state is to be understood, in contrast on the molten state of the melt electrolyte material in the effective area of the electrolyte matrix.

For example, if the melt electrolyte in the electrolyte matrix is eutectic Mixture of K2CO3 and Li2CO3 is used as sealing material in the edge area z. B. pure K2CO3 or pure Li2CO3 used or a mixture of both Components, however, in contrast to the mixture in the effective range of Electrolyte matrix has a higher melting point, so that it at the working temperature Fuel cell is essentially solid.  

Fig. 2 shows in cross section a view of the edge of the fuel cell with a seal according to a second embodiment of the invention. Here again, an electrolyte matrix 1 5 is arranged to form respective gas spaces between an anode 4 and a cathode, wherein the gas spaces of the anode and cathode to the outside are sealed by sealing strips 2 and 3. FIG. Similar to the conventional type of seal according to FIG. 4, the electrolyte matrix 1 with the matrix material soaked in the melt electrolyte also extends in part between the two sealing strips 2 and 3 . The actual edge seal, however, is formed by a member separate from the electrolyte matrix 1 sealing element 1 B, which consists of a matrix material which is impregnated by a chemically related with the water contained in the electrolyte matrix 1 electrolyte fusible material which is solid at the working temperature of the cell is substantially is, similar to the sealing element 1 A in the embodiment shown in Fig. 1. As in the case of the first embodiment, the sealing material of the sealing element 1 B can either consist essentially of one of the components of the melt electrolyte, or of a mixture of the components of the electrolyte, but with such a mixing ratio that the melting point is higher than that of the electrolyte mixture in the effective area of the electrolyte matrix 1 between the anode 4 and cathode 5 and which is above the working temperature of the fuel cell, or the sealing material can be formed by a glass or a glass-like substance which contains at least one of the components of the electrolyte as a mixture component.

According to a further exemplary embodiment of the invention shown in FIG. 3, the anode 4 and the cathode 5 can be guided together with the electrolyte matrix i as a package into the edge region of the fuel cell and can be sealed directly with the formation of sealing elements or sealing strips 4 A and 5 A. To seal the gas spaces of anode 4 and cathode 5 , the pores in the edge area of the fuel cell are impregnated with the sealing material and thereby made gas-tight, so that the sealing elements or sealing strips 4 A and 5 A form an integral part of anode 4 and cathode 5 become. This eliminates the mechanical point of discontinuity that occurs in the conventional case by extending the electrolyte matrix beyond the electrodes.

Claims (10)

1. Fuel cell with an electrolyte-containing electrolyte matrix ( 1 ), an anode ( 4 ) arranged on one side of the electrolyte matrix ( 1 ) and a cathode ( 5 ) arranged on the opposite side of the electrolyte matrix ( 1 ), and with the gas space of the anode ( 4 ) and the cathode ( 5 ) in the edge area of the fuel cell sealing sealing strips ( 2 , 3 ) and a sealing element of the electrolyte matrix ( 1 ) extending between the sealing strips ( 2 , 3 ) for sealing their edge area, characterized in that the sealing element (1 a, 1 B) of the electrolyte matrix (1) by the water contained in the electrolyte matrix (1) electrolyte chemically related fusible material is formed, which is solid at the working temperature of the cell substantially. 2. Fuel cell according to claim 1, characterized in that the Sealing material consists essentially of one of the components of a mixture existing electrolytes. 3. Fuel cell according to claim 2, characterized in that the Sealing material made of K2CO3 or Li2CO3. 4. Fuel cell according to claim 1, characterized in that the sealing material consists essentially of a mixture of the components of the electrolyte, which has a higher melting point than the electrolyte mixture in the effective region of the electrolyte matrix ( 1 ) between the anode ( 4 ) and cathode ( 5 ) . 5. Fuel cell according to claim 4, characterized in that the Sealing material consists of a mixture of K2CO3 and Li2CO3. 6. Fuel cell according to one of claims 1 to 5, characterized in that as Sealing material a glass or a glass-like substance is used, at least contains one of the components of the electrolyte as a component of the mixture. 7. Fuel cell according to one of claims 1 to 6, characterized in that the sealing material is tough plastic at the working temperature of the fuel cell. 8. Fuel cell according to one of claims 1 to 7, characterized in that the matrix material of the electrolyte matrix ( 1 ) is impregnated gas-tight in the edge region of the fuel cell with the sealing material. 9. Fuel cell according to one of claims 1 to 8, characterized in that the anode ( 4 ) and / or cathode ( 5 ) together with the electrolyte matrix ( 1 ) are guided into the edge region of the fuel cell and in the edge region of the fuel cell with the sealing material are impregnated in a gastight manner, as a result of which sealing strips or sealing elements ( 4 A, 5 A) are formed which seal the gas space of the anode ( 4 ) and cathode ( 5 ). 10. Fuel cell according to one of claims 1 to 9, characterized in that the sealing material becomes molten in the edge area at higher temperatures introduced and is solid or viscous at the working temperature of the fuel cell.