WO2022084014A1 - Membrane-electrode assembly for an electrochemical cell and method for the production of a membrane-electrode assembly - Google Patents

Abstract

Membrane-electrode assembly (1) for an electrochemical cell (100), the membrane-electrode assembly (1) having a frame structure (10). The frame structure (10) comprises a first film (11) and a second film (12) with an adhesive (13) in between. At least one spacer (20) is arranged in the adhesive (13).

Description

description

title

Membrane-electrode assembly for an electrochemical cell and method for producing a membrane-electrode assembly

State of the art

A fuel cell is an electrochemical cell that has two electrodes that are separated from one another by means of an ion-conducting electrolyte. The fuel cell converts the energy of a chemical reaction of a fuel with an oxidant 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 an active area of a PEM-FC, two porous electrodes with a catalyst layer adjoin a polymer electrolyte membrane (PEM). The PEM-FC also includes gas diffusion layers (GDL) in the active area, which delimit the polymer electrolyte membrane (PEM) and the two porous electrodes with a catalyst layer on both sides. The PEM, the two electrodes with the catalyst layer and optionally also the two GDLs can form a so-called membrane-electrode unit (MEA) in the active area of the PEM-FC. Two opposing bipolar plates (halves), in turn, delimit 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 with an anode plate of a bipolar plate, and the oxidizing agent, in particular air/oxygen, is distributed with a cathode plate of the bipolar plate. To electrically insulate adjacent bipolar plates, to stabilize the shape of the MEA and to prevent unwanted escape of the fuel or the oxidizing agent, the MEA are enclosed in a frame-like opening of two foils arranged next to one another. The two films of this frame structure are usually made of the same material, for example polyethylene naphthalate (PEN). The two foils formed from the same material can dispensably have redundant properties, for example electrical insulating ability (electrically insulating) and/or oxygen impermeability of each of the two foils.

DE 101 40 684 A1 discloses a membrane-electrode unit for a fuel cell containing a layered arrangement of an anode electrode, a cathode electrode and a membrane arranged between them, with a polymer material on a top and bottom side of the layered arrangement is applied.

DE 10 2018 131 092 A1 has a membrane electrode unit with a frame structure.

The object of the present invention is to prevent an adhesive from being squeezed out of the frame structure and preferably to ensure a defined height of the frame structure.

Disclosure of Invention

For this purpose, the membrane-electrode assembly includes a frame structure. The frame structure has a first film and a second film with an interposed adhesive. At least one spacer is arranged in the adhesive.

The membrane-electrode assembly can include a membrane, in particular a polymer electrolyte membrane (PEM). The membrane-electrode unit can further comprise two porous electrodes, each with a catalyst layer, these being arranged in particular on the PEM and delimiting it on both sides. One can speak here in particular of an MEA-3. In addition, the membrane electrode assembly can include two gas diffusion layers. This can in particular limit the MEA-3 on both sides. One can speak here in particular of an MEA-5.

The electrochemical cell can be, for example, a fuel cell, an electrolytic cell or a battery cell. The fuel cell is in particular a PEM-FC (polymer electrolyte membrane fuel cell). A cell stack comprises, in particular, a multiplicity of electrochemical cells arranged one above the other.

In particular, the frame structure has a frame shape. The frame structure is preferably designed to be circumferential. A membrane and the two electrodes can thus be enclosed in the frame structure in a particularly advantageous manner. Furthermore, the cross-section of the frame structure is in particular U-shaped or Y-shaped to accommodate the membrane and the two electrodes between the legs of the U-shape or Y-shape.

The adhesive preferably seals the membrane-electrode unit from the outside, glues the two foils together and fixes the membrane with the two electrodes in the frame structure.

The adhesive can also preferably be electrically insulating. The frame structure can thus be particularly advantageously electrically insulating and an undesired flow of current in an inactive region of the electrochemical cell can be particularly advantageously kept low, in particular prevented.

The spacers set a defined distance between the two foils and prevent further compression of the frame structure during the stacking process and thus pressing out of the adhesive. A defined height of the electrochemical cell is thus maintained in a robust manner.

The spacer can be in the form of a long fiber or a mesh. The number can thus be limited to a single spacer. In alternative embodiments, a plurality of spacers can be arranged in the adhesive. The spacers are then preferably spherical, rod-shaped, cube-shaped or fibrous. The combination of adhesive and spacer is designed to be quasi-homogeneous, the spacers are stochastically distributed particles in the adhesive.

More preferably, the spacer(s) can also be insulating, in particular electrically insulating, so that an undesired flow of current is prevented. The spacer is particularly preferably made of glass, Al2O3 or plastic.

In advantageous developments, a gas diffusion layer is attached to the frame structure by means of a further adhesive. The additional adhesive also has at least one spacer. Here, too, the spacer(s) are preferably designed according to one of the embodiments described above.

The invention also includes a method for producing a membrane-electrode unit according to one of the above statements. The process has the following process steps:

• Deploying the first slide

• Applying the adhesive to the first foil

• Adding the spacer into the adhesive

• Place the membrane - optionally coated with the electrodes - on the first foil

• Gluing the first foil to the second foil with the membrane interposed in sections

When gluing the two foils, they are preferably glued only to the middle leg of the Y-shape, with the membrane being arranged between the other two legs. The membrane can also be glued to both films.

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 from the Features and/or advantages resulting from the claims, the description or the drawings, including structural details, spatial arrangements and method steps, can be essential to the invention both on their own 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.

They show schematically:

1 shows a membrane-electrode unit from the prior art, only the essential areas being shown.

2 shows a membrane-electrode unit according to the invention, only the essential areas being shown.

FIG. 1 shows a section of a membrane-electrode unit 1 of an electrochemical cell 100, in particular a fuel cell, from the prior art in a vertical section, only the essential areas being shown.

The membrane-electrode unit 1 has a membrane 2, for example a polymer electrolyte membrane (PEM), and two porous electrodes 3 and 4, each with a catalyst layer, the electrodes 3 and 4 being arranged on one side of the membrane 2 in each case. Furthermore, the electrochemical cell 100 has, in particular, two gas diffusion layers 5 and 6, which can also belong to the membrane-electrode unit 1, depending on the design.

The membrane electrode assembly 1 is surrounded on its periphery by a frame structure 10, which is also referred to as a subgasket. The frame structure 10 is used for rigidity and tightness of the membrane-electrode unit 1 and is a non-active area of the electrochemical cell 100. The frame structure 10 is particularly U-shaped or Y-shaped in section, with a first leg of the U-shaped frame section being formed by a first film 11 made of a first material W1 and a second leg of the U-shaped frame section being formed by a second Foil 12 is formed from a second material W2. In addition, the first film 11 and the second film 12 are glued together by means of an adhesive 13 made of a third material W3. The first material W1 and the second material W2 are often identical. k

The two gas diffusion layers 5 and 6 are in turn each arranged on one side of the frame structure 10 by means of a further adhesive 14, usually in such a way that they are in contact with one electrode 3, 4 each over the active surface of the electrochemical cell 100.

When several electrochemical cells 100 are braced to form a cell stack, there is a risk that the adhesive 13 will be pressed out of the frame structure 10 . This can lead to leaks in the membrane-electrode unit 1 and as a result even to the total failure of the entire cell stack.

According to the invention, spacers 20 are now inserted between the first film 11 and the second film 12, so that a defined distance between these two films 11, 12 is maintained and the adhesive 13 is prevented from being squeezed out. The spacers are preferably defined particles and are added to the adhesive 13 .

For this purpose, FIG. 2 shows a plurality of spacers 20 which are spherical in this embodiment and are arranged in the adhesive 13 . The diameter of the spacers 20 preferably corresponds exactly to the height to which the adhesive 13 is to be compressed during the clamping of the cell stack. Further compression is avoided due to the comparatively high rigidity of the spacers 20.

The spacers 20 transmit the clamping force of the cell stack in the compressed state from the first film 11 to the second film 12 and maintain a defined distance between the two films 11, 12; a Pressing out of the adhesive 13 from the frame structure 10 is thus avoided. The shape of the spacers 20 can be, for example, spheres, rods, cubes or fibers. A net or a very long fiber can also serve as spacer 20 .

The material of the spacers 20 is advantageously an insulating material such as glass, Al2O3 or plastics. Particularly preferred plastics here are PEN, EPDM, FKM, silicones, urethanes, PP and PPS. The spacers 20 can the adhesive 13 before or after

Apply to one of the two films 11, 12 are added.

The additional adhesive 14 between the frame structure 10 and the two gas diffusion layers 5, 6 can also be provided with spacers 20 analogously.

Claims

- 8 - Claims

First membrane-electrode assembly (1) for an electrochemical cell (100), wherein the membrane-electrode assembly (1) has a frame structure (10), wherein the frame structure (10) has a first film (11) and a second Foil (12) with an adhesive (13) interposed, characterized in that at least one spacer (20) is arranged in the adhesive (13).

2. Membrane-electrode unit (1) according to claim 1, characterized in that the spacer (20) is designed as a long fiber or as a network.

3. Membrane electrode assembly (1) according to claim 1, characterized in that a plurality of spacers (20) are arranged in the adhesive (13), the spacers (20) being spherical, rod-shaped, cube-shaped or fibrous.

4. membrane electrode assembly (1) according to any one of claims 1 to 3, characterized in that the / the spacer (20) consists of an insulating material.

5. Membrane-electrode unit (1) according to claim 4, characterized in that the spacer(s) (20) consists of glass, Al2O3 or plastic.

6. Membrane-electrode assembly (1) according to any one of claims 1 to 5, characterized in that a gas diffusion layer (5, 6) is attached to the frame structure (10) by means of a further adhesive (14), the further adhesive ( 14) also has at least one spacer (20). - 9 - Method for producing a membrane electrode unit (1) according to one of claims 1 to 6, characterized by the following method steps: • Providing the first film (11)

• Applying the adhesive (13) to the first foil (11)

• Adding the spacer (20) into the adhesive (13)

• Place the membrane (2) - optionally coated with the electrodes (3, 4) - on the first film (11) • Glue the first film (11) to the second film (12) with the membrane (2) interposed in sections