EP4073857A1 - Method for producing a fuel cell, device for producing a membrane-electrode arrangement for a fuel cell, fuel cell and fuel-cell stack - Google Patents

Abstract

The invention relates to a method for producing a fuel cell (1), comprising the steps of a) preparing a plurality of catalyst pastes (16), which differ at least with respect to a parameter influencing the catalytic activity, b) filling at least two of the plurality of catalyst pastes (16) into a first applicator means (17) comprising a number of chambers (18) corresponding to the number of catalyst pastes (16) to be introduced, wherein only one of the catalyst pastes (16) is introduced into each of the chambers (18), c) filling at least two of the plurality of catalyst pastes (16) into a second applicator means (17), comprising a number of chambers (18) corresponding to the number of catalyst pastes (16) to be introduced, wherein only one of the catalyst pastes (16) is introduced into each of the chambers (18), d) coating, by way of the first applicator means (17), a first side of a sheet of film (20) of an electrolyte membrane (2) taken past the first applicator means (17) and the second applicator means (17), e) coating, by way of the second applicator means (17), a second side of the sheet of film (20), f) cutting the resulting coated electrolyte membrane (2) to size from the sheet of film (20) and turning the electrolyte membrane (2) by 90° with respect to a conveying direction (21) of the sheet of film (20), g) placing the electrolyte membrane (2) between two flux-field plates with a parameter-related gradient oriented perpendicularly to the flux field, and h) pressing the flux-field plates. The invention also relates to a device for producing a membrane-electrode arrangement for a fuel cell (1), to a fuel cell (1) and to a fuel-cell stack.

Description

Process for the production of a fuel cell,

Device for producing a membrane electrode assembly for a

Fuel cell,

Fuel cell and fuel cell stacks

DESCRIPTION:

The invention relates to a method for producing a fuel cell, comprising the steps of a) preparing a plurality of catalyst pastes which differ at least with regard to one parameter influencing the catalytic property, b) filling at least two of the plurality of catalyst pastes into a first application tool one of the number of chambers corresponding to the number of catalyst pastes to be filled in, only one of the catalyst pastes being filled into each of the chambers, c) filling of at least two of the plurality of catalyst pastes into a second application tool with a number of chambers corresponding to the number of catalyst pastes to be filled, wherein only one of the catalyst pastes is poured into each of the chambers, d) coating a first side of a sheet of electrolyte membrane passed by the first application tool and the second application tool by means of the first application tool, e ) Coating a second side of the film web by means of the second application tool, f) cutting the electrolyte membrane from the film web and rotating the electrolyte membrane by 90 ° with respect to a conveying direction of the film web, g) placing the electrolyte membrane between two flow field plates with a gradient oriented perpendicular to the flow field with regard to the parameter, and h) pressing the flow field plates. The invention further relates to a device for fixing a membrane electrode arrangement for a fuel cell, a fuel cell and a fuel cell stack. The term catalytic property is to be understood broadly and also includes the time behavior, the stability of the electrodes and / or their tendency to feed and remove reactants, in particular the porosity. The catalyst pastes differ in their constituents and additives which, when dry, lead to electrode sheets with the corresponding properties.

Fuel cell devices are used for the chemical conversion of a fuel with oxygen to water in order to generate electrical energy. For this purpose, fuel cells contain an electrolyte and associated electrodes as a core component. When the fuel cell device is in operation with a plurality of fuel cells combined to form a fuel cell stack, the fuel, in particular hydrogen (H2) or a hydrogen-containing gas mixture, is fed to the anode. In the case of a hydrogen-containing gas, this is first reformed to provide hydrogen. Electrochemical oxidation of H2 to FT takes place at the anode, releasing electrons. The electrons provided at the anode are fed to the cathode via an electrical line. Oxygen or an oxygen-containing gas mixture is fed to the cathode, so that a reduction of O2 to O ² takes place with the absorption of the electrons.

In solid oxide fuel cells, the electrolyte consists of a solid ceramic material that is able to conduct oxygen ions but has an insulating effect on electrons. The operating temperatures for these solid oxide fuel cells are between 650 ° C and 1000 ° C. In polymer electrolyte membrane (PEM) fuel cells, the electrolyte consists of a solid polymer membrane, such as the one under the name Nafion is known. PEM fuel cells have significantly lower operating temperatures and are preferably used in mobile applications without using waste heat. EP 2 660 918 A2 describes a solid oxide fuel cell that uses hydrocarbons such as methane as fuel, which is first reformed to form hydrogen. This leads to a large temperature difference within the solid oxide fuel cell, which affects its mechanical and chemical durability. In order to mitigate this, the use of a graduated electrode is proposed, in which a cata- lyst arch is used, in which the catalyst content changes gradually. The catalyst arch is manufactured in such a way that a plurality of regions with a different catalyst content are formed, so that a gradient in the flow direction of the fuel is provided with respect to the catalyst content in order to reduce the temperature differences. For this purpose, a transfer film is coated by means of a long slot nozzle with several chambers, which are used to hold different catalyst pastes. The solid oxide fuel cell itself is manufactured in that a layer is formed from separately manufactured sheets, namely an electrolyte sheet, a functional sheet sheet, a support sheet sheet and the catalyst sheet, which is then subjected to a sintering process.

DE 10 2016 224 398 A1 describes a device for producing a membrane electrode assembly for a PEM fuel cell, in which an electrolyte membrane is unwound by an electrolyte feed device and fed to a transfer section, with a first catalyst coating device on one side of the electrolyte membrane ne homogeneous catalyst coating and on the other side of the electrolyte membrane with a second catalyst coating device a homogeneous catalyst layer is applied. DE 102007 014046 A1 describes a fuel cell in which adjacent areas are designed with different diffusion transports for educts and products. So far, only electrodes for fuel cells that are made up of homogeneous electrode layers can be manufactured on an industrial scale. For the operation of fuel cells, however, it can be advantageous if the electrodes have a gradient with regard to one property in the flow direction given away by the flow field parallel to the alignment of the membrane, i.e. not homogeneous but graded electrodes. Properties of the electrodes are, for example, their catalytic activity, hydrophobicity, surface area, porosity and the like. The graded property is understood to mean the graded distribution of one of the above properties, which are determined by the parameters set out below for the graded electrode.

The object of the present invention is to provide a method for producing a fuel cell with a graded electrode which can be used on an industrial scale. The object is also to provide a device for Fierstellen a membrane electrode assembly with a gra ed electrode, an improved fuel cell and an improved fuel cell stack. This object is achieved by a method with the features of claim 1, by a device with the features of claim 7, by a fuel cell with the features of claim 8 and by a fuel cell stack according to claim 9. Advantageous configurations with expedient developments of the invention are specified in the dependent claims.

The method mentioned at the outset is characterized in that it enables great variability with regard to the properties of the electrodes of a membrane electrode arrangement, in particular the possibility exists of specially adapting a catalyst layer applied to the electrolyte membrane for an electrode with regard to its properties along the associated flow field in its direction of flow. The other electrode can be designed conventionally, that is to say without a property gradient, or else it can be graded. The membrane electrode assembly manufactured in this way tion is cut to size and the cut is rotated so that the gradient is in the desired orientation along the flow field of the flow field plates. The gradient can be increasing or decreasing. There is the possibility of varying the catalytic property over a wide range in that the catalytic parameter is selected from a group comprising a type of catalyst, a catalyst loading, a type of catalyst support, an ionomer type, an ionomer concentration, a porosity. It should be pointed out that more than one parameter can be varied according to the method mentioned at the outset.

It is provided that the catalyst pastes applied to one side of the film web touch one another at the edge, as this also creates the possibility that the catalyst pastes mix in the edge areas and the difference between the catalyst pastes is partially compensated for, that is there is no grading with regard to the catalytic activity.

In order not to mechanically overload the electrolyte membrane during the coating with the catalyst layer, it is provided that steps d) and e) are carried out one after the other.

Before step f), that is to say cutting the electrolyte membrane to size, a drying step can be carried out in order to enable and simplify the further processing of the membrane electrode arrangement.

It is preferred here that a slot nozzle or a coating doctor is used as the application means, since these means have proven themselves for industrial coating processes with moving webs or foils.

A device for Fierstellen a membrane electrode assembly for a fuel cell according to the above-mentioned method comprises an electrolyte membrane feed device, through which an electrolyte membrane can be unwound from a supply roll and fed to a web path on which a first application means with a plurality of chambers on a first side of the Railway path and a second application means with a A plurality of chambers arranged on a second side of the web path, as well as a drying unit arranged downstream of the first application means and the second application means. A fuel cell produced according to the above-mentioned method is optimized with regard to its properties and, in particular, has a higher degree of efficiency and thus a higher efficiency, since the fuel usage and the water management can be improved. This also leads to a longer service life and lower costs.

A fuel cell stack has a plurality of fuel cells, at least one of the fuel cells being provided with a plurality of catalyst pastes due to its position within the fuel cell stack, at least one of which is different from the catalyst pastes of the others with regard to at least one parameter influencing the catalytic activity Differentiate between fuel cells. This fuel cell is thus optimized, but it is also possible for several fuel cells in the fuel cell stack to be provided with a property gradient. This gradient of properties does not have to be the same for all fuel cells; in particular, the terminal fuel cells can have a gradient of properties that deviates from the central fuel cells.

The features and feature combinations mentioned above in the description as well as the features and feature combinations mentioned below in the description of the figures and / or shown alone in the figures can be used not only in the specified combination, but also in other combinations or on their own, without the To leave the scope of the invention. There are thus also embodiments to be regarded as encompassed and disclosed by the invention, which are not explicitly shown or explained in the figures, but emerge from the explained embodiments and can be generated by separate combinations of features. Further advantages, features and details of the invention emerge from the claims, the following description of preferred Ausfüh approximate forms and with reference to the drawings. 1 shows a schematic representation of the structure of a fuel cell,

FIG. 2 shows a detailed view II, shown only schematically, of an electrode from FIG. 1,

Fig. 3 is a schematic representation of a device for Fierstel len a membrane electrode assembly in a side view,

4 shows a plan view of an electrolyte membrane coated with a plurality of catalyst pastes by means of a slot nozzle, with the property gradient symbolized by the arrow with regard to a catalytic activity, and FIG

5 shows a plan view of the blank of the electrolyte membrane after it has been rotated through 90 °, with the direction of flow in the flow field symbolized by the arrow.

A fuel cell 1 is shown in FIG. Here, a semipermeable electrolyte membrane 2 is covered on a first side 3 with a first electrode 4, in this case the anode, and on a second side 5 with a second electrode 6, in this case the cathode. The first electrode 4 and the second electrode 6 comprise carrier particles 14 on which catalyst particles 13 made of noble metals or mixtures comprising noble metals such as platinum, palladium, ruthenium or the like are arranged or supported. These catalyst particles 13 serve as reaction accelerators in the electrochemical reaction of the fuel cell 1. The carrier particles 14 can contain carbon. But there are also carrier particles 14 into consideration, which are formed from a metal oxide or carbon with a corre sponding coating. In such a polymer electrolyte membrane Fuel cells (PEM fuel cells) are split up into protons and electrons at the first electrode 5 (anode), fuel or fuel molecules, in particular hydrogen. The electrolyte membrane 2 lets the protons (eg H ⁺ ) through, but is impermeable to the electrons (e-). In this exemplary embodiment, the electrolyte membrane 2 is formed from a monomer, preferably a sulfonated tetrafluoroethylene polymer (PTFE) or a polymer of perfluorinated sulfonic acid (PFSA). The following reaction takes place at the anode: 2H2 -> 4FT + 4e ^_ (Oxidation / electron release).

While the protons pass through the electrolyte membrane 2 to the second electrode 6 (cathode), the electrons are conducted to the cathode or to an energy store via an external circuit. A cathode gas, in particular oxygen or air containing oxygen, is provided at the cathode, so that the following reaction takes place here: O2 + 4FT + 4e ^_ -> 2H2O (reduction / electron uptake).

In the present case, the electrodes 4, 6 are each assigned a gas diffusion layer 7, 8, of which one gas diffusion layer 7 is assigned to the anode and the other gas diffusion layer 8 is assigned to the cathode. In addition, the gas diffusion layer 7 on the anode side is assigned a flow field plate designed as a bipolar plate 9 for supplying the fuel gas, which has a fuel flow field 11. By means of the fuel flow field 11, the fuel is fed through the gas diffusion layer 7 to the electrode 4. On the cathode side, the gas diffusion layer 8 is assigned a flow field plate, which includes a cathode gas flow field 12 and is also designed as a bipolar plate 10, for supplying the cathode gas to the electrode 6.

It should be noted that the electrodes 4, 6 can also be present as an integral part of the gas diffusion layers 7, 8. The gas diffusion layers 7, 8 can also comprise a microporous layer (MPL). In the present case, the electrodes 4, 6 are formed with a plurality of catalyst particles 13, which can be formed as nanoparticles, for example as core-shell nanoparticles (“core-shell nanoparticles”). They have the advantage of a great deal Surface, wherein the noble metal or the noble metal alloy is only arranged on the surface, while a lower-value metal, for example nickel or copper, form the core of the nanoparticle. The catalyst particles 13 are arranged or supported on a plurality of electrically conductive carrier particles 14. In addition, an ionomer binder 15, which is preferably formed from the same material as the membrane 2, is present between the carrier particles 14 and / or the catalyst particles 13. This ionomer binder 15 is preferably formed as a polymer or ionomer containing a perfluorinated sulfonic acid. The ionomer binder 15 is present in porous form, which has a porosity of greater than 30 percent. This ensures, in particular on the cathode side, that the oxygen diffusion resistance is not increased and thus a lower loading of the catalyst particle 13 with noble metal or a lower loading of the carrier particles 14 with catalyst particles 13 is possible (FIG. 2).

The lowering position of the electrodes 4, 6 will be explained below. First, the catalyst particles 13 supported on carrier particles 14 are suspended in a solution of an ionomer binder 15. The solution of the ionomer binder 15 preferably contains between 15 and 25 percent by weight (% by weight), preferably exactly 20% by weight of a polymer of perfluorinated sulfonic acid. Isopropanol can also be added. At the same time or subsequently, an inorganic foaming agent is also suspended and a catalyst paste 16 is formed. In the method according to the invention for producing a fuel cell 1, a plurality of catalyst pastes 16 are produced which differ at least with regard to one parameter influencing the catalytic property. Then at least two catalyst pastes 16 from the plurality of catalyst pastes 16 are placed in a first application means 17 with one of the number to be filled

Catalyst pastes 16 filled corresponding number of chambers 18, wherein only one of the catalyst pastes 16 is filled into each of the chambers 18. As an example, reference can be made to an application means 17 designed as a slot nozzle or a coating doctor blade, which has 7 chambers has so that up to 7 different catalyst pastes 16 can be filled. Another number of catalyst pastes 16 and chambers is possible. The procedure for the second side of the electrolyte membrane 2 is comparable, in that at least two of the plurality of catalyst pastes 16 are filled into a second application means with a number of chambers 18 corresponding to the number of catalyst pastes 16 to be filled, with only one of the catalyst pastes 16 in each of the chambers 18 is filled. Here, too, more than two chambers 18 can be implemented. It should also be noted that the majority of the catalyst pastes 16 can then comprise up to 14, but possibly also partially identical catalyst pastes 16 can be used on the sides. After the application means 17 have been filled, a first side of a film web 20 of an electrolyte membrane 2 guided past the first application means 17 and the second application means 17 is coated by means of the first application means 17 and a second side of the film web is coated by means of the second application means 17. These steps can in principle take place simultaneously, but it is advantageous if these steps are carried out one after the other and then the applied catalyst pastes 16 are dried with a drying unit 19 to form a catalyst layer for the electrode. Subsequently, a blank 26 is formed from the electrolyte membrane 2 from the film web 20 and the electrolyte membrane 2 is rotated by 90 ° with respect to a conveying direction 21 of the film web 20 in order to obtain the desired orientation of the property gradient in the flow direction 22 of the flow field, as is the case for The area marked in FIG. 2 is shown in the application in FIG.

The electrolyte membrane 2 is then placed between two flow field plates, the bipolar plates 9, 10 with the orientation perpendicular to the flow field. Entente gradients with regard to the parameter, and the compression of the flow field plates.

The catalytic parameter is selected from a group which comprises a type of catalyst, a catalyst loading, a type of catalyst carrier, an ionomer type, an ionomer concentration, a porosity.

FIGS. 4 and 5 show that the catalyst pastes 16 applied to one side of the film web 20 touch one another at their edge, so that the formation of a gradient instead of a gradation of the catalytic activity is promoted.

The device shown in Figure 3 for Fierstellen a membrane electrode assembly for a fuel cell 1 comprises an electrolyte membrane feed device 22, through which an electrolyte membrane 2 can be unwound from a supply roll and fed to a path 24 on which a first application means 17 with a plurality of Chambers 18 are arranged on a first side of the web path 24 and a second application means 17 with a plurality of chambers 18 is arranged on a second side of the web path 24. To improve clarity, only one of the application means 17 is shown. Furthermore, there is a drying unit 19 arranged downstream of the first application means 17 and the second application means 17. The electrolyte membrane 2 processed in this way and transformed into a membrane electrode arrangement can be collected on a coil 25 before further processing.

In a fuel cell stack with a plurality of fuel cells 1, at least one of the fuel cells 1 is provided with a plurality of catalyst pastes 16 due to its position within the fuel cell stack, of which at least one of the catalyst pastes 16 of the at least one parameter influencing the catalytic activity is different other fuel cells 1 differs. Preferably, the terminal fuel cells 1 in particular have a property gradient that differs from the central fuel cells 1. REFERENCE CHARACTERISTICS LIST:

1 fuel cell

2 electrolyte membrane 3 first side of the membrane

4 electrode / anode

5 second side of the membrane

6 electrode / cathode

7 anode-side gas diffusion layer 8 cathode-side gas diffusion layer

9 Bipolar plate fuel gas

10 bipolar plate cathode gas

11 Fuel flow field

12 cathode gas flow field 13 catalyst particles

14 carrier particles

15 ionomer binders

16 catalyst paste

17 application means 18 chamber

19 drying unit

20 film web

21 Direction of conveyance

22 Direction of flow 23 Electrolyte membrane feed device

24 railway path

25 coil

26 cutting

27 edge

Claims

EXPECTATIONS:

1. A method for producing a fuel cell (1), comprising the steps of a) preparing a plurality of catalyst pastes (16) which differ at least with regard to one parameter influencing the catalytic activity, b) filling at least two of the plurality of catalyst pastes ( 16) in a first application tool (17) with one of the number of catalyst pastes (16) to be filled in corresponds to the number of chambers, with only one of the catalyst pastes (16) being filled into each of the chambers, c) filling of at least two of the plurality of catalyst pastes th (16) in a second application tool (17) with one of the number of catalyst pastes (16) to be filled correspond to the number of chambers (18), with only one of the catalyst pastes (16) being filled into each of the chambers (18), d) Coating of a first side of a film web (20) of an electrolyte that is guided past the first application means (17) and the second application tool (17) embranch (2) by means of the first application tool (17), e) coating a second side of the film web (20) by means of the second application tool (17), f) cutting the electrolyte membrane (2) from the film web (20) and twisting the electrolyte membrane ( 2) at 90 ° with respect to a conveying direction (21) of the film web (20), g) placing the electrolyte membrane (2) between two flow field plates with a gradient oriented perpendicular to the flow field with regard to the parameter, and h) pressing the flow field plates.

2. The method according to claim 1, characterized in that the catalytic parameter is selected from a group which comprises a Catalyst type, a catalyst loading, a catalyst carrier type, an ionomer type, an ionomer concentration, a porosity.

3. The method according to claim 1 or 2, characterized in that the catalyst paste (16) applied to one side of the film web (20) touch one another at the edge.

4. The method according to any one of claims 1 to 3, characterized in that steps d) and e) are carried out one after the other.

5. The method according to any one of claims 1 to 4, characterized in that a step of drying is carried out before step f).

6. The method according to any one of claims 1 to 5, characterized in that a slot nozzle or a coating doctor is used as the application means (17).

7. Device for producing a membrane electrode assembly for a fuel cell (1) according to claims 1 to 6, with an electrolyte membrane feed device (23) through which an electrolyte membrane (2) can be unwound from a supply roll and attached to a web path (24) can be fed, on which a first application means (17) with a plurality of chambers (18) on a first side of the web path (24) and a second application means (17) with a plurality of chambers (18) on a second side of the web path (24) net angeord, and with a downstream of the first application means (17) and the second application means (17) arranged drying unit (19).

8. Fuel cell produced by a method according to one of claims 1 to 6.

9. Fuel cell stack with a plurality of fuel cells (1) according to claim 8, characterized in that at least one of the fuel cells (1) is provided with a plurality of catalyst pastes (16) due to its position within the fuel cell stack is, of which at least one differ from the catalyst pastes (16) of the other fuel cells (1) at least with regard to one parameter influencing the catalytic activity.

10. The fuel cell stack according to claim 9, characterized in that the terminal fuel cells (1) have a property gradient that differs from the central fuel cells (1).