DE102022205356A1 - Arrangement, gasket MEA system, fuel cell stack and method for producing an arrangement - Google Patents

Abstract

Arrangement (100) for a fuel cell of a fuel cell stack (200), the arrangement (100) having: - a plate-shaped membrane (10) with an anode side (11), a cathode side (12) opposite the anode side (11) and a membrane - Outer lateral surface (13), - a gasket (20), in particular plate-shaped gasket, with a first gasket side (21), a second gasket side (22) opposite the first gasket side (21), the gasket (20) having an opening (28). the first gasket side (21) to the second gasket side (22), the gasket (20) having a gasket inner jacket surface (23) formed by the opening (28), - a connecting body (30a, 30b), at least the membrane (10) is arranged in the opening (28) of the gasket (20), the gasket (20) being connected at least in sections to the membrane (10) by means of at least the connecting body (30a, 30b).

Description

State of the art

The invention relates to an arrangement, a gasket MEA system, a fuel cell stack and methods for producing an arrangement according to the invention.

A fuel cell is an electrochemical cell that has two electrodes that are separated from each other by means of an ion-conducting electrolyte. The fuel cell converts the energy from a chemical reaction of a fuel with an oxidizer directly into electricity. There are different types of fuel cells.

A special type of fuel cell is the polymer electrolyte membrane fuel cell (PEM-FC). In a PEM-FC, two porous electrodes (anode or cathode) with a catalyst layer adjoin a polymer electrolyte membrane (PEM). The PEM-FC also includes gas diffusion layers (GDL), which delimit the polymer electrolyte membrane (PEM) and the two porous electrodes with a catalyst layer on both sides. The polymer electrolyte membrane, the two electrodes with the catalyst layer and the two gas diffusion layers form a so-called membrane electrode unit (MEA). Bipolar plates, in turn, limit the MEA on both sides. A fuel cell stack is made up of MEA and bipolar plates arranged alternately one above the other. The fuel, in particular hydrogen, is distributed on an anode side of a bipolar plate, and the oxidizing agent, in particular air/oxygen, is distributed on a cathode side of the bipolar plate.

For better handling and electrical insulation, the PEM together with the two porous electrodes can also be enclosed between two foils (PEN foils). The two films are coated with an adhesive and are joined together to form a subgasket, for example using a lamination process. The disadvantage is that such films are particularly expensive. Furthermore, part of the active surface of a fuel cell can be covered by the adhesive of the gasket foils. Furthermore, an MEA designed in this way can have a non-functional air gap between a gas diffusion layer of the MEA and an electrode of the MEA.

Disclosure of the invention

The present invention shows an arrangement according to the features of claim 1, a gasket MEA system according to the features of claim 8, a fuel cell stack according to the features of claim 9 and a method according to the features of claim 10.

Further features and details of the invention emerge from the subclaims, the description and the drawings. Features and details that are described in connection with the arrangement according to the invention naturally also apply in connection with the gasket MEA system according to the invention, the fuel cell stack according to the invention and the method according to the invention and vice versa, so that the disclosure of the individual aspects of the invention is always reciprocal is or can be referred to.

According to a first aspect, the present invention shows an arrangement for a fuel cell of a fuel cell stack, wherein the arrangement has a plate-shaped membrane with an anode side, a cathode side opposite the anode side and a membrane outer surface. Furthermore, the arrangement comprises a gasket, in particular a plate-shaped gasket, with a first gasket side, a second gasket side opposite the first gasket side, the gasket having an opening from the first gasket side to the second gasket side, and wherein the gasket has a gasket formed by the opening. Has inner surface. The arrangement further comprises a connecting body. In addition, in the arrangement, at least the membrane is arranged in the opening of the gasket, and the gasket is connected at least in sections to the membrane, in particular in a materially bonded manner, by means of at least the connecting body.

The membrane is in particular arranged at least in an active region of a fuel cell of a fuel cell stack.

The membrane can be, for example, a Nanfion membrane (Nafion™).

In particular, the membrane outer surface of the plate-shaped membrane connects the anode side of the plate-shaped membrane with the cathode silk of the plate-shaped membrane. The outer membrane surface is formed in particular by an outer edge of the membrane.

In particular, the gasket is plate-shaped. Furthermore, in particular the first gasket side of the plate-shaped gasket is a first plate side of the gasket and the second gasket side of the plate-shaped gasket is a second plate side opposite the first plate side Gaskets. The plate-shaped gasket can be film-like.

The gasket has a gasket inner surface and a gasket outer surface. The gasket inner surface is to be understood as the surface of the gasket which is formed by the opening in the gasket. In particular, the gasket inner surface is formed by an inner edge of the gasket formed by the opening in the gasket. In particular, the gasket inner lateral surface of the gasket connects the first gasket side and the second gasket side opposite the first gasket side. The gasket outer surface is formed in particular by an outer edge of the gasket. The opening of the gasket can also be understood as a breakthrough through the gasket.

The expression “at least in sections” used in the previous paragraphs and following paragraphs can be understood in particular as “at least in sections along the inner edge of the gasket and/or as at least in sections along the outer edge of the membrane”.

The arrangement can have one or more connecting bodies. Details and/or features and/or advantages that are mentioned in the preceding and/or subsequent paragraphs regarding the at least one connecting body can also be transferred to the other (further) connecting bodies, and vice versa.

Advantageously, the number of components can be kept particularly low with an arrangement according to the invention. The arrangement of membrane, gasket and connecting body can therefore be particularly cost-effective. Furthermore, with the arrangement according to the invention, a gasket MEA system can be provided in which an active surface for generating electrical energy is not covered by the connecting body. In addition, a non-functional air gap between a gas diffusion layer and a porous electrode can be eliminated. A fuel cell stack can therefore be operated particularly advantageously and manufactured particularly cheaply.

It can be advantageous if, in an arrangement according to the invention, the gasket inner surface of the gasket and the membrane outer surface of the membrane are at least partially opposite one another, at least in sections. The arrangement can therefore be manufactured particularly simply, be geometrically compact and be mechanically stable. Furthermore, gasket material can be saved. In particular, the inner gasket surface of the gasket and the membrane outer surface of the membrane can lie directly opposite one another. In other words, the inner surface of the gasket of the gasket can be arranged not offset, in particular not offset in a stacking direction of the fuel cell stack, from the membrane outer surface of the membrane.

Advantageously, in an arrangement according to the invention, the gasket inner surface and the membrane outer surface can contact each other at least in sections, in particular a connecting body at least in sections on the first gasket side of the gasket and on the anode side of the membrane for connecting, in particular cohesively connecting, the gasket to the membrane is arranged and/or wherein in particular a (further) connecting body is arranged at least in sections on the second gasket side of the gasket and on the cathode side of the membrane for connecting, in particular for cohesively connecting, the gasket to the membrane. This means that adhesive can be saved particularly advantageously and the arrangement can be particularly mechanically stable, so that the arrangement for stacking the components of a fuel cell stack to form the fuel cell stack can be handled particularly precisely. Preferably, the gasket inner surface and the membrane outer surface contact each other along the entire inner edge of the gasket formed by the opening in the gasket. The arrangement can therefore be particularly mechanically stable. The expression: “the gasket inner surface and the membrane outer surface contact each other at least in sections” is intended to express that the gasket inner surface and the membrane outer surface contact each other directly, at least in sections. In other words, in particular, there is no further body, at least in sections, between the gasket inner surface and the membrane outer surface. Furthermore, in particular the connecting body arranged at least in sections on the first gasket side of the gasket and on the anode side of the membrane is plate-shaped or layer-shaped and / or the (further) connecting body arranged at least in sections on the second gasket side of the gasket and on the cathode side of the membrane is plate-shaped or designed in layers. The arrangement can therefore be designed to be particularly simple.

With particular advantage, in an arrangement according to the invention, the gasket inner surface of the gasket and the membrane outer surface of the membrane can be spaced apart from one another at least in sections, in particular the at least one connecting body is arranged in sections between the gasket inner surface of the gasket and the membrane outer surface of the membrane for connecting, in particular for cohesively connecting, the gasket to the membrane. A connection, in particular a cohesive connection, can thus be produced particularly securely between the gasket and the membrane. Preferably, at least in sections, the at least one connecting body is on the first gasket side of the gasket and on the anode side of the membrane and on the second gasket side of the gasket and on the cathode side of the membrane and between the gasket inner surface of the gasket and the membrane outer surface of the membrane for connection , in particular for materially connecting, the gasket is arranged with the membrane. The arrangement can therefore be manufactured particularly simply and/or the tightness between the anode side and cathode side of a fluid-tight connecting body can be particularly high. The at least one connecting body is in particular formed or arranged in one piece, for example by means of a dispensing process or a jet process. In a vertical section, the at least one connecting body can be H-shaped or essentially H-shaped.

According to a further preferred embodiment, in an arrangement according to the invention, the gasket can be formed in one piece, in particular the arrangement having only a single gasket. Advantageously, according to the invention, it is not necessary to surround a membrane, in particular a polymer electrolyte membrane, together with the two porous electrodes between two foils (PEN foils). The arrangement can therefore have a particularly reduced number of components and can therefore be designed to be particularly cost-effective and simple. The gasket can also have a plastic and/or ceramic and/or a metal. The gasket is preferably made of plastic. For example, the gasket can be a PEN film (polyethylene naphthalate).

It can be advantageous if, in an arrangement according to the invention, the at least one connecting means is at least partially an adhesive and/or that the at least one connecting means is at least partially an adhesive-free polymer, in particular an elastomer. By using an adhesive at least in sections, the arrangement can be particularly advantageously connected to one another in a materially bonded manner. Furthermore, the arrangement can be particularly mechanically stable, so that a tightness of the arrangement can be particularly advantageous and further handling of the arrangement can be particularly advantageous for a fuel cell stack. By using an adhesive-free polymer at least in sections, the arrangement can be particularly cost-effective, with sealing being able to be achieved in particular by pressing the fuel cell stack.

Advantageously, in an arrangement according to the invention, the at least one connecting body can be fluid-tight or substantially fluid-tight for at least one of the process gases of the fuel cell of the fuel cell stack and/or the at least one connecting body is electrically insulating. Preferably, the at least one connecting body is fluid-tight or essentially fluid-tight at least for the oxidizing agent, for example air, of the fuel cell and fluid-tight or essentially fluid-tight for the reducing agent, for example hydrogen, of the fuel cell. This ensures that the arrangement is tight. In other words, it can be prevented that the reducing agent and the oxidizing agent can get to each other at a connection point (via the connection body). Furthermore, the connecting body is advantageously electrically insulating. This means that an electrical short circuit in a fuel cell can be prevented.

According to a second aspect, the present invention shows a gasket MEA system, wherein the gasket MEA system has an arrangement designed according to the invention. Furthermore, the gasket MEA system comprises an anode arranged on the anode side of the membrane of the arrangement, the anode having a gas diffusion layer side facing away from the membrane. Furthermore, the gasket MEA system comprises a cathode arranged on the cathode side of the membrane of the arrangement, wherein the cathode has a gas diffusion layer side facing away from the membrane. Furthermore, the gasket MEA system comprises a cathode arranged at least on the gas diffusion layer side of the anode, in particular arranged in a materially bonded manner, first gas diffusion layer. Furthermore, the gasket MEA system comprises a second gas diffusion layer arranged at least on the gas diffusion layer side of the cathode, in particular arranged in a cohesive manner. Furthermore, in the gasket MEA system, the arrangement with the membrane and the gasket as well as the anode, the cathode, the first gas diffusion layer and the second gas diffusion layer are at least partially connected to one another by means of at least the at least one connecting body of the arrangement, in particular at least partially connected to one another in a materially bonded manner .

The connecting body in particular has at least one inner surface of the connecting body. The at least one connecting body can be connected to the inner surface of the connecting body to an anode outer surface of the anode and/or be arranged on the cathode outer surface of the cathode, preferably arranged directly.

Furthermore, the at least one connecting body can comprise a first gas diffusion layer side contacting the first gas diffusion layer and/or the at least one connecting body or a further connecting body can comprise a second gas diffusion layer side contacting the second gas diffusion layer. In particular, the first gas diffusion layer can be arranged on the gas diffusion layer side of the anode and on the first gas diffusion layer side of the connecting body and/or in particular the second gas diffusion layer can be arranged on the gas diffusion layer side of the cathode and on the second gas diffusion layer side of the connecting body or the further connecting body.

In particular, the first gas diffusion layer is also designed in the shape of a plate and/or the second gas diffusion layer is designed in the shape of a plate.

The gasket MEA system according to the second aspect of the invention therefore has the same advantages as have already been described for the arrangement according to the first aspect of the invention.

According to a third aspect, the present invention shows a fuel cell stack, wherein the fuel cell stack comprises a first separator plate and a second separator plate. Furthermore, the fuel cell stack comprises an arrangement designed according to the invention arranged between the first separator plate and the second separator plate or a gasket MEA system designed according to the invention arranged between the first separator plate and the second separator plate.

In particular, the first separator plate is plate-shaped and/or the second separator plate is plate-shaped. The first separator plate can also be understood as a first bipolar plate and/or the second separator plate can also be understood as a second bipolar plate.

The fuel cell stack according to the third aspect of the invention therefore has the same advantages as have already been described for the arrangement according to the first aspect of the invention or the gasket MEA system according to the second aspect of the invention.

According to a fourth aspect, the present invention shows a method for producing an arrangement, in particular an arrangement according to the invention, for a fuel cell of a fuel cell stack, the method comprising, as one step, providing a plate-shaped membrane with an anode side, a cathode side opposite the anode side and a membrane side. Has outer surface area. The method comprises, as a further step, providing a gasket, in particular a film-like gasket, with a first gasket side, a second gasket side opposite the first gasket side, wherein the gasket has an opening from the first gasket side to the second gasket side, and wherein the gasket has a Gasket inner surface formed by the opening. The method further comprises, as a further step, arranging at least the membrane in the opening of the gasket. The method also includes, as a further step, at least a sectional connection, in particular a at least sectional cohesive connection, of at least the gasket by means of at least one connecting body with the membrane arranged in the opening of the gasket.

The method steps described above and those described below can, if technically sensible, be carried out individually, together, simply, multiple times, in parallel and/or one after the other in any order.

The at least partially cohesive connection of at least the gasket by means of at least one connecting body to the membrane arranged in the opening of the gasket is, in particular, bonding.

In particular, the membrane can have an anode already arranged on the anode side of the membrane of the arrangement, the anode having a gas diffusion layer side facing away from the membrane, and/or with a cathode already arranged on the cathode side of the membrane of the arrangement, the cathode having a gas diffusion layer side facing away from the membrane Gas diffusion layer side can be provided. The production of an arrangement with the membrane, the gasket and the anode and the cathode can therefore be carried out particularly easily.

Furthermore, in particular, a first gas diffusion layer that can be arranged at least on the gas diffusion layer side of the anode can be provided and/or a second second gas diffusion layer that can be arranged at least on the gas diffusion layer side of the cathode can be provided. The first gas diffusion layer can serve as a carrier material for the at least one connecting body and/or the second gas diffusion layer can serve as a carrier material for the at least one or a further connecting body. E.g. A first gas diffusion layer can be provided and an adhesive can then be arranged on a surface of the first gas diffusion layer, in particular on an edge region of the first gas diffusion layer, for example by means of a dispensing method.

The method according to the fourth aspect of the invention therefore has the same advantages as those already associated with the arrangement according to the first aspect of the invention or the MEA gasket system according to the second aspect of the invention or the fuel cell stack according to the third aspect of the invention have been described.

Further measures improving the invention result from the following description of some exemplary embodiments of the invention, which are shown schematically in the figures. All features and/or advantages arising from the claims, the description or the drawings, including constructive details, spatial arrangements and method steps, can be essential to the invention both individually and in the various combinations. It should be noted that the figures are only descriptive and are not intended to limit the invention in any way.

• 1 eine Anordnung,
• 2 eine Anordnung,
• 3 ein Gasket-MEA-System,
• 4 einen Brennstoffzellenstapel, und
• 5 ein Verfahren.

It shows schematically:

• 1 an arrangement,
• 2 an arrangement,
• 3 a gasket MEA system,
• 4 a fuel cell stack, and
• 5 a procedure.

In the following figures, identical reference numbers are used for the same technical features of different exemplary embodiments.

1 discloses in a vertical section a part of an arrangement 100 according to the invention for a fuel cell of a fuel cell stack 200, the arrangement 100 comprising a plate-shaped membrane 10 with an anode side 11, a cathode side 12 opposite the anode side 11 and a membrane outer surface 13. Furthermore, the arrangement 100 comprises a one-piece gasket 20, in particular a plate-shaped gasket 20, with a first gasket side 21, a second gasket side 22 opposite the first gasket side 21, the gasket 20 having an opening 28 from the first gasket side 21 to the second gasket side 22 and wherein the gasket 20 has a gasket inner surface 23 formed by the opening 28. The arrangement 100 further comprises a connecting body 30a and a further connecting body 30b. Furthermore, in the arrangement 100, at least the membrane 10 is arranged in the opening 28 of the gasket 20, the gasket 20 being connected at least in sections to the membrane 10 by means of at least the connecting body 30a and by means of the further connecting body 30b, in particular connected in a materially bonded manner. In 1 The gasket inner surface 23 and the membrane outer surface 13 can also lie opposite one another. Additionally is in 1 the arrangement is designed in such a way that the gasket inner surface 23 and the membrane outer surface 13 contact each other, in particular the at least one connecting body 30a on the first gasket side 21 of the gasket 20 and on the anode side 11 of the membrane 10 for connecting, in particular for cohesively connecting , of the gasket 20 is arranged with the membrane 10 and in particular the further connecting body 30b is arranged at least in sections on the second gasket side 22 of the gasket 20 and on the cathode side 12 of the membrane 10 for connecting, in particular for cohesively connecting, the gasket 20 with the membrane 10 is arranged. Furthermore, the at least one connecting means 30a and the further connecting means 30b can also be an adhesive. It is also conceivable that the connecting agent is a non-adhesive polymer, for example an elastomer. Furthermore, the at least one connecting body 30a and the further connecting body 30b can each be fluid-tight or substantially fluid-tight for the oxidizing agent and the reducing agent as process gases of the fuel cell of the fuel cell stack 200. In addition, the at least one connecting body 30a and the further connecting body 30b are advantageously each electrically insulating.

2 shows a vertical section of part of an arrangement 100, in particular as it already is 1 has been described. In 2 the gasket inner surface 23 of the gasket 20 and the membrane outer surface 13 of the membrane 10 are at least partially spaced apart from one another, with the at least one connecting body 30a between the gasket inner surface 23 of the gasket 20 and the membrane outer surface 13 of the membrane 10 for connecting the Gaskets 20 is arranged with the membrane 10. Furthermore, the connecting body 30a is also arranged, in particular arranged directly, on the first gasket side 21 of the gasket 20 and on the anode side 11 of the membrane 10 as well as on the second gasket side 22 of the gasket 20 and on the cathode side 12 of the membrane 10. In other words, a continuous adhesive phase is particularly conceivable. The at least one connecting body 30a points in the vertical section in particular has an H-shape or essentially an H-shape (lying H).

3 discloses in a vertical section a part of a gasket MEA system 150, wherein the gasket MEA system 150 is an arrangement 100 designed according to the invention,
and an anode 160 arranged on the anode side 11 of the membrane 10 of the arrangement 100, the anode 160 having a gas diffusion layer side 161 facing away from the membrane 10. The gasket MEA system 150 further comprises a cathode 170 arranged on the cathode side 12 of the membrane 10 of the arrangement 100, the cathode 170 having a gas diffusion layer side 171 facing away from the membrane 10. In addition, the gasket MEA system 150 includes a first gas diffusion layer 180 arranged at least on the gas diffusion layer side 161 of the anode 160. In addition, the gasket MEA system 150 includes a second gas diffusion layer 190 arranged at least on the gas diffusion layer side 171 of the cathode 170. In addition, in the Gasket MEA system 150, the arrangement 100 with the membrane 10 and the gasket 20 as well as the anode 160, the cathode 170, the first gas diffusion layer 180 and the second gas diffusion layer 190 are connected to one another at least in sections by means of at least the at least one connecting body 30a of the arrangement 100, in particular at least partially connected to one another in a materially bonded manner. Such a sandwich structure is particularly mechanically stable, which is particularly advantageous for precise handling when stacking to form the fuel cell stack 200. Furthermore, the gasket 20 protrudes laterally in particular.

4 discloses in a vertical section a part of a fuel cell stack 200, wherein the fuel cell stack 200 comprises a first separator plate 210 and a second separator plate 220. In addition, the fuel cell stack 200 includes a gasket MEA system 150 designed according to the invention, arranged between the first separator plate 210 and the second separator plate 200, as is the case, for example 3 has been described. Furthermore, the gasket 20 protrudes laterally in particular.

5 discloses a method for producing an arrangement 100 for a fuel cell of a fuel cell stack 200. The method has, as a first step, providing 300 a plate-shaped membrane 10 with an anode side 11, a cathode side 12 opposite the anode side 11 and a membrane outer surface 13. As a further step, the method includes providing a gasket 20, in particular a film-like gasket, with a first gasket side 21, a second gasket side 22 opposite the first gasket side 21, the gasket 22 having an opening 28 from the first gasket side 21 to the second gasket side 22, and wherein the gasket 20 has a gasket inner surface 23 formed by the opening 28. As a further step, the method includes arranging 320 at least the membrane 10 in the opening 28 of the gasket 20 or vice versa. As a further step, the method includes at least a sectional connection 340, in particular a circumferential connection, of at least the gasket 20 by means of at least one connecting body 30a with the membrane 10 arranged in the opening 28 of the gasket 20.

Claims (10)

Arrangement (100) for a fuel cell of a fuel cell stack (200), the arrangement (100) having: - a plate-shaped membrane (10) with an anode side (11), a cathode side (12) opposite the anode side (11) and an outer membrane surface (13), - a gasket (20), in particular a plate-shaped gasket, with a first gasket side (21), a second gasket side (22) opposite the first gasket side (21), the gasket (20) having an opening (28) from the first gasket side (21 ) to the second gasket side (22), the gasket (20) having an inner gasket surface (23) formed by the opening (28), - a connecting body (30a, 30b), at least the membrane (10) being arranged in the opening (28) of the gasket (20), the gasket (20) being at least partially connected to the membrane by means of at least the connecting body (30a, 30b). (10) is connected. Arrangement (100) according to Claim 1 , characterized in that the gasket inner surface (23) and the membrane outer surface (13) are at least partially opposite one another, at least in sections. Arrangement (100) according to one of the preceding claims, characterized in that the gasket inner surface (23) and the membrane outer surface (13) contact each other at least in sections, in particular a connecting body (30a, 30b) at least in sections on the first gasket side (100) 21) of the gasket (20) and on the anode side (11) of the membrane (10) for connecting the gasket (20) to the membrane (10) is arranged and / or in particular one (further) connecting body (30a, 30b) at least in sections on the second gasket side (22) of the gasket (20) and on the cathode side (12) of the membrane (10) to the connection which of the gasket (20) is arranged with the membrane (10). Arrangement (100) according to one of the preceding claims, characterized in that the gasket inner surface (23) of the gasket (20) and the membrane outer surface (13) of the membrane (10) are spaced apart from one another at least in sections, in particular the at least one Connecting body (30a, 30b) is arranged at least in sections between the gasket inner surface (23) of the gasket (20) and the membrane outer surface (13) of the membrane (10) for connecting the gasket (20) to the membrane (10). Arrangement (100) according to one of the preceding claims, characterized in that the gasket (20) is formed in one piece, in particular the arrangement (100) having only a single gasket (20). Arrangement (100) according to one of the preceding claims, characterized in that the at least one connecting means (30a, 30b) is at least partially an adhesive and / or that the at least one connecting means (30a, 30b) is at least partially an adhesive-free polymer, in particular an elastomer is. Arrangement (100) according to one of the preceding claims, characterized in that the at least one connecting body (30a, 30b) is fluid-tight or substantially fluid-tight for at least one of the process gases of the fuel cell of the fuel cell stack (200) and/or that the at least one connecting body ( 30a, 30b) is electrically insulating. Gasket MEA system (150), the gasket MEA system (150) comprising: - an arrangement (100) designed according to one of the preceding claims, - an anode (160) arranged on the anode side (11) of the membrane (10) of the arrangement (100), the anode (160) having a gas diffusion layer side (161) facing away from the membrane (10), - a cathode (170) arranged on the cathode side (12) of the membrane (10) of the arrangement (100), the cathode (170) having a gas diffusion layer side (171) facing away from the membrane (10), - a first gas diffusion layer (180) arranged at least on the gas diffusion layer side (161) of the anode (160), - a second gas diffusion layer (190) arranged at least on the gas diffusion layer side (171) of the cathode (170), the arrangement (100) with the membrane (10) and the gasket (20) as well as the anode (160), the cathode (170 ), the first gas diffusion layer (180) and the second gas diffusion layer (190) are connected to one another at least in sections by means of at least the at least one connecting body (30a, 30b) of the arrangement (100). Fuel cell stack (200), wherein the fuel cell stack (200) has: - a first separator plate (210) and a second separator plate (220), - one arranged between the first separator plate (210) and the second separator plate (220), according to one of Claims 1 until 7 trained arrangement (100) or one arranged between the first separator plate (210) and the second separator plate (200). Claim 8 trained gasket MEA system (150). Method for producing an arrangement (100) for a fuel cell of a fuel cell stack (200), the method comprising: - Providing (300) a plate-shaped membrane (10) with an anode side (11), a cathode side (12) opposite the anode side (11) and an outer membrane surface (13), - Providing (310) a gasket (20), in particular a film-like gasket, with a first gasket side (21), a second gasket side (22) opposite the first gasket side (21), the gasket (22) having an opening (28). the first gasket side (21) to the second gasket side (22), and wherein the gasket (20) has a gasket inner surface (23) formed by the opening (28), - Arranging (320) at least the membrane (10) in the opening (28) of the gasket (20), - at least partially connecting (340) at least the gasket (20) by means of at least one connecting body (30a, 30b) with the membrane (10) arranged in the opening (28) of the gasket (20).

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