DE102020216363A1 - Process for producing a membrane-electrode assembly, membrane-electrode assembly and fuel cell with a membrane-electrode assembly - Google Patents

Abstract

The invention relates to a method for producing a membrane electrode assembly (10) for a fuel cell, comprising the steps of providing a membrane (1), preferably a polymer membrane, forming electrodes (2, 3) by coating the membrane ( 1) with a catalytically active material, - forming a gasket (4) enclosing the membrane (1) in at least one edge region (A) using two plastic films (6, 7) and an adhesive (5). According to the invention, when forming the Gaskets (4), the two plastic films (6, 7) are applied to the coated membrane (1) on both sides in the edge area (A) and glued together outside the edge area (A). The invention also relates to a membrane electrode assembly (10) and a fuel cell with a membrane electrode assembly (10) according to the invention.

Description

The invention relates to a method for producing a membrane electrode assembly according to the preamble of claim 1. The invention also relates to a membrane electrode assembly and a fuel cell having a membrane electrode assembly according to the invention.

State of the art

A fuel cell can be used to convert chemical energy into electrical energy using a fuel, for example hydrogen, and an oxidizing agent, for example oxygen. For this purpose, the fuel cell has a membrane-electrode assembly (MEA) with a membrane that is coated on both sides with a catalytically active material to form electrodes. To reinforce the edges, the membrane, which is coated on both sides, is usually laminated between two plastic films. This type of edge reinforcement is also called "gasket". The two plastic films have large windows so that the coated membrane remains free except for a narrow peripheral edge area. The free surfaces form active surfaces via which the proton exchange required for the electrochemical reaction takes place during operation of the fuel cell.

When the gasket is formed or when the coated membrane is laminated in, approx. 6% of the active area is covered by adhesive and thus deactivated. This has a negative effect on the performance of the fuel cell.

The object of the present invention is therefore to improve the performance of a fuel cell with a laminated membrane electrode assembly. Furthermore, the membrane electrode assembly should be as simple and inexpensive to produce.

To solve the problem, the method with the features of claim 1 and the membrane electrode assembly with the features of claim 6 are proposed. Advantageous developments of the invention can be found in the respective dependent claims. Furthermore, a fuel cell with a membrane electrode assembly according to the invention is specified.

Disclosure of Invention

• - Bereitstellen einer Membran, vorzugsweise einer Polymermembran,
• - Ausbilden von Elektroden durch beidseitiges Beschichten der Membran mit einem katalytisch aktiven Material,
• - Ausbilden eines die Membran in zumindest einem Randbereich einfassenden Gaskets unter Verwendung von zwei Kunststofffolien und eines Klebstoffs.

The proposed method for producing a membrane electrode assembly for a fuel cell comprises the steps

• - providing a membrane, preferably a polymer membrane,
• - forming electrodes by coating the membrane on both sides with a catalytically active material,
• Forming a gasket enclosing the membrane in at least one edge region using two plastic films and an adhesive.

According to the invention, when the gasket is being formed, the two plastic films are laid against the coated membrane on both sides in the edge area and are glued to one another outside the edge area.

The active surfaces in the edge area of the membrane thus remain free of adhesive, specifically on both sides, ie both on the anode side and on the cathode side. Since the active areas are not covered by the adhesive, they are not deactivated either. The plastic foils lying on both sides of the membrane in the edge area alone do not lead to a deactivation of the active surfaces, since the reaction gases can also get under the plastic foils. The active surfaces thus extend under the plastic foils. This leads to an enlargement of the active areas and thus to an improvement in the performance of the membrane electrode assembly and the fuel cell produced from it.

Since the plastic films are not bonded over their entire surface in the proposed method, adhesive can also be saved. This reduces the costs of producing the membrane electrode assembly. Furthermore, membrane electrode assemblies produced according to the proposed method have a lower weight. The coated membrane is held in the gasket by the rigidity of the plastic foils. In this way, an edge reinforcement is also achieved without directly gluing the plastic films to the membrane.

The adhesive used to bond the two plastic films is preferably only applied in regions to one or both plastic films. This means that the at least one plastic film remains free of adhesive in some areas. When applying the adhesive, the area that should remain free of adhesive can be covered with a shadow mask or the like.

Furthermore, when applying the adhesive to one or both plastic films, an area is preferably left free that is the same width as the bordered edge area of the membrane. About that In addition, further areas can be left free, provided that it is ensured that the two plastic films are secured against slipping.

If the adhesive also serves as a seal or gas barrier, it is preferably brought up to the edge area of the membrane. An end face of the membrane is preferably glued to the plastic films. This ensures that the active surfaces on both sides of the membrane remain free, but that the glued-in front surface does not allow gas exchange. It is harmless if a small part of the adhesive is pressed into the edge area when the plastic films are placed on the membrane and/or during a subsequent lamination process, so that the active surfaces in the edge area are not completely free of adhesive. This is within an allowable tolerance range and does not conflict with the claims.

Furthermore, the plastic films are preferably provided with gaps before and/or after the adhesive bonding. First recesses can be used, for example, to form media channels. These are preferably arranged in end sections of the plastic films. The recesses can in particular be punched-out areas. These can be introduced into the plastic films before or after they are glued together. Further recesses or punched-out areas preferably serve to form window-like openings to expose the active areas of the coated membrane. These recesses or punched-out areas can only be produced before the plastic films are glued.

In order to solve the problem mentioned at the outset, a membrane-electrode assembly for a fuel cell is also proposed. This comprises a membrane, preferably a polymer membrane, which is coated on both sides with a catalytically active material to form a first and a second electrode and is surrounded by a gasket in at least one edge area. The gasket is made of plastic foils that are in contact with the membrane on both sides and are glued to one with the aid of an adhesive. According to the invention, the plastic films are free of adhesive at least in an area that overlaps with the edge area of the membrane. The active surface in the edge area of the membrane is therefore not covered by adhesive and consequently not deactivated either. This is because the plastic films lying against the membrane do not prevent the reaction gases from getting between the plastic films and the membrane. This increases the active area on both sides of the membrane. The membrane-electrode assembly or the fuel cell produced from it thus has improved performance. At the same time, the consumption of adhesive is reduced. Furthermore, the weight of the membrane-electrode assembly and of the fuel cell produced from it is reduced.

The proposed membrane electrode assembly can be produced in particular by the method according to the invention described above.

According to a preferred embodiment of the invention, the adhesive-free area of the plastic film has the same width as the bordered edge area of the membrane. This is to prevent adhesive from getting between the plastic films and the membrane. However, this cannot be completely ruled out and is within a tolerance range that does not contradict the invention.

The adhesive preferably reaches up to an end face of the membrane, so that the end face of the membrane is glued to the plastic films. The bonding on the end face does not limit the active surfaces of the coated membrane, so that this has no disadvantage in terms of the performance of the membrane-electrode assembly or the fuel cell. If the membrane is glued on the face side, the glue can also be used as a seal or gas barrier, which prevents gas transfer from one electrode side to the other electrode side.

Furthermore, the plastic films preferably have recesses, preferably punched-out portions, for the formation of media channels. The recesses or punched-out areas overlap one another, so that media channels are formed in a stacked arrangement of fuel cells of the same type. The media channels serve to supply the fuel cell with the respective reaction gas.

The plastic films preferably have further recesses or punched-out portions, which, however, have been introduced into the gasket before it is formed. These recesses or punched-out areas are large-area, window-like openings for exposing the active areas of the coated membrane. With the help of these plastic films, a circumferential edge reinforcement or a circumferential gasket can be formed that has a sufficiently high level of rigidity to hold the membrane. Direct bonding of the edge area of the membrane to the gasket is therefore not required.

In addition, a fuel cell for a fuel cell stack is proposed, which comprises a membrane electrode assembly according to the invention. The fuel cell has thanks to the membrane electrode assembly according to the invention a better performance. In addition, it can be produced more cost-effectively since adhesive is saved. The material savings also reduce the weight of the fuel cell.

• 1 eine perspektivische Darstellung der einzelnen Elemente einer erfindungsgemäßen Membran-Elektroden-Anordnung vor dem Verkleben,
• 2 eine perspektivische Darstellung der Elemente der 1 nach dem Verkleben und
• 3 einen schematischen Querschnitt durch die erfindungsgemäße Membran-Elektroden-Anordnung der 1 und 2.

A preferred embodiment of the invention is explained in more detail below with reference to the accompanying drawings. These show:

• 1 a perspective view of the individual elements of a membrane electrode assembly according to the invention before gluing,
• 2 a perspective view of the elements of the 1 after gluing and
• 3 a schematic cross section through the membrane electrode assembly according to the invention 1 and 2 .

Detailed description of the drawings

1 1 shows a membrane 1 coated on both sides with a catalytically active material and two plastic films 6 , 7 which serve to form a gasket 4 . For this purpose, the two plastic films 6, 7 are placed on both sides of the coated membrane 1 in an edge area A and glued together outside of the edge area A.

The two plastic films 6, 7 are of the same design, so that they cover one another after gluing. This also applies to cutouts 8, 9 provided in the plastic films 6, 7. The cutouts 8 are each formed in end sections 11, 12 of the plastic films 6, 7, so that media channels are formed on both sides of the membrane 1. The recesses 9 each serve to form a large window that leaves a large area of the coated membrane 1 free. This is the active area of the coated membrane 1.

Again 1 can be seen, the recesses 9 are each bordered by an area B which remains free of adhesive 5 . This means that the adhesive 5 for gluing the plastic films 6, 7 is only applied to the plastic films 6, 7 or at least one plastic film outside of the area B. The area B has a width that corresponds to the width of the edge area A (see Fig 3 ). The plastic foils 6 , 7 are therefore essentially only glued to one another, but not to the edge area A of the membrane 1 .

The membrane 1, which is coated on both sides, and the plastic films 6, 7 bonded to form a gasket 4 together form a membrane-electrode assembly 10 (see FIG 2 ), the two-sided coatings of the membrane 1 forming electrodes 2, 3 with a catalytically active material.

The structure of the membrane electrode assembly 10 is in 3 shown. From this it can be seen that the adhesive bonding of the plastic films 6 , 7 to one another also leads to an adhesive bonding of the plastic films 6 , 7 to the membrane 1 . However, the adhesion is limited to the area of an end face 13 of the membrane, so that the active areas of the membrane 1 are not restricted. This is because the edge region A remains free of adhesive 5. The gasket 4 is therefore only glued to the membrane 1 on the front side. The bonding on the face side forms a gas barrier which prevents gas from getting from one electrode side to the other electrode side of the membrane-electrode assembly 10 .

Claims (10)

Method for producing a membrane-electrode assembly (10) for a fuel cell, comprising the steps - providing a membrane (1), preferably a polymer membrane, - forming electrodes (2, 3) by coating the membrane (1) on both sides with a catalytically active material, - forming a gasket (4) enclosing the membrane (1) in at least one edge region (A) using two plastic films (6, 7) and an adhesive (5), characterized in that when forming the gasket ( 4) the two plastic films (6, 7) are placed on both sides of the coated membrane (1) in the edge area (A) and glued together outside of the edge area (A). procedure after claim 1 , characterized in that the adhesive (5) used to bond the two plastic films (6, 7) is applied to one or both plastic films (6, 7) only in certain areas. procedure after claim 1 or 2 , characterized in that when the adhesive (5) is applied to one or both plastic films (6, 7), an area (B) is left free which is the same width as the bordered edge area (A) of the membrane (1). Method according to one of the preceding claims, characterized in that an end face (13) of the membrane (1) is glued to the plastic films (6, 7). Method according to one of the preceding claims, characterized in that before and/or after gluing the plastic films (6, 7) are provided with recesses (8, 9), preferably punched out. Membrane-electrode assembly (10) for a fuel cell, comprising a membrane (1), preferably a polymer membrane, which is coated on both sides with a catalytically active material to form a first and a second electrode (2, 3) and is coated in at least one edge region ( A) is surrounded by a gasket (4) which is formed from plastic films (6, 7) which are in contact with the membrane on both sides and are bonded to one another with the aid of an adhesive (5), characterized in that the plastic films (6, 7) are free of adhesive at least in an overlapping area with the edge area (A) of the membrane (1). Membrane electrode assembly (10) after claim 6 , characterized in that the adhesive-free area of the plastic films (6, 7) is the same width as the bordered edge area (A) of the membrane (1). Membrane electrode assembly (10) after claim 6 or 7 , characterized in that the adhesive (5) reaches up to an end face (13) of the membrane (1), so that the membrane (1) is glued to the plastic films (6, 7) at the front. Membrane electrode assembly (10) after claim 7 or 8th , characterized in that the plastic films (6, 7) have recesses (8, 9), preferably punched out, for the formation of media channels. Fuel cell for a fuel cell stack, comprising a membrane electrode assembly (10) according to one of Claims 6 until 9 .

Images