WO2022135957A1

WO2022135957A1 - Electrode unit, and process for manufacturing an electrode unit

Info

Publication number: WO2022135957A1
Application number: PCT/EP2021/084979
Authority: WO
Inventors: Friedrich Kneule; Andreas Haeffelin
Original assignee: Robert Bosch Gmbh
Priority date: 2020-12-22
Filing date: 2021-12-09
Publication date: 2022-06-30
Also published as: DE102020216475A1; CN116686121A; EP4268302A1

Abstract

The invention relates to an electrode unit for a preferably supported, in particular metal-supported, fuel cell and/or electrolyzer unit (10a; 10b), in particular a solid oxide fuel cell unit, which includes a plurality of functional layers (14a, 16a, 18a, 20a, 22a; 14b, 16b, 18b, 20b, 22b). According to the invention, at least one of the functional layers (16a; 14b, 16b, 18b, 20b, 22b) has a specifically variable layer thickness (28a; 28b, 52b, 54b, 56b, 58b) over its active cell area.

Description

description

Electrode assembly and method of manufacturing an electrode assembly

State of the art

An electrode unit for a preferably supported, in particular metal-supported, fuel cell and/or electrolyzer unit, in particular solid oxide fuel cell unit, which has a plurality of functional layers, has already been proposed.

Disclosure of Invention

The invention is based on an electrode unit for a preferably supported, in particular metal-supported, fuel cell and/or electrolyzer unit, in particular solid oxide fuel cell unit, which has a plurality of functional layers.

It is proposed that at least one of the functional layers has a specifically variable layer thickness over its active cell area. A “fuel cell and/or electrolyzer unit” should preferably be understood to mean at least a part, in particular a subassembly, of a fuel cell, in particular a solid oxide fuel cell, in particular a planar one, and/or an electrolyzer, in particular a high-temperature electrolyzer, in particular for stationary or mobile applications . In particular, the metal-supported fuel cell and/or electrolyzer unit can also be the entire fuel cell, in particular the entire solid oxide fuel cell, the entire electrolyzer, in particular the entire high-temperature electrolyzer, a stack of fuel cells and/or electrolyzers and/or a combination of several stacks of fuel cells and/or electrolyzers include. The preferably supported, in particular metal-supported, fuel cell and/or electrolyzer unit is preferably provided to burn a fuel with the supply of an oxidant in a combustion process to generate electrical energy. Alternatively or additionally, the metal-supported fuel cell and/or electrolyzer unit is provided for dividing a fluid into at least two components in a separation process with the supply of electrical energy. For the fuel cell and/or electrolyzer unit, different construction concepts, such as a planar or tubular construction, as well as different mechanical support concepts are preferably conceivable. In addition to the metal-supported structure (MSC), an electrolyte-supported structure (ESC), an anode-supported structure (ASC), a cathode-supported structure (CSC) or an inner-supported structure (ISC) are also conceivable.

An "electrode unit" of a fuel cell and/or electrolyzer unit should preferably be understood to mean a unit which comprises at least one electrode, in particular a functional layer designed as an electrode layer, which is directly connected to the combustion process carried out by means of the fuel cell and/or electrolyzer unit and/or separation process involved. The electrode unit preferably comprises, in particular in addition to the electrode, at least one further electrode, in particular a further functional layer designed as an electrode layer. In particular, the electrode and the further electrode are intended for use as a cathode-anode pair. The electrode unit preferably comprises at least one separating element, in particular a functional layer designed as an electrolyte layer. The separating element is preferably arranged between the electrode and the further electrode. The electrode and/or the further electrode is preferably designed as an oxidant electrode, in particular for contact with the oxidant and/or a cleavage product. At least the electrode and/or the further electrode is preferably designed as a fuel electrode, in particular for contact with the fuel and/or a further fission product.

Preferably, under a "functional layer of a preferably supported, in particular metal-supported, fuel cell and/or electrolyzer unit" in particular a layer is to be understood that is directly involved in the combustion process and/or the separation process carried out by means of the preferably supported, in particular metal-supported, fuel cell and/or electrolyzer unit. In particular, at least one, preferably two functional layers is designed as an electrode layer, in particular for use as a cathode and/or anode. At least one electrode layer is preferably designed as an oxidant electrode, in particular for contact with the oxidant and/or a cleavage product. At least one electrode layer is preferably designed as a fuel electrode, in particular for contact with the fuel and/or another fission product. At least one functional layer is preferably designed as a separating layer, in particular as an electrolyte layer. At least one separating layer is preferably arranged on at least one electrode layer, in particular between two electrode layers. The electrode unit preferably comprises at least one of the functional layers designed as an electrode layer. The electrode unit preferably comprises at least one functional layer designed as a separating layer.

In particular, the electrode unit is designed as a membrane electrode assembly (MEA). “Provided” should be understood to mean, in particular, specially set up, specially designed and/or specially equipped. The fact that an object is provided for a specific function is to be understood in particular to mean that the object fulfills and/or executes this specific function in at least one application and/or operating state.

The electrode unit preferably has a carrier element on which the functional layers are applied. The individual functional layers are layered on top of each other and applied to the carrier element. The support element can preferably be planar or tubular. The functional layers are continuous in an active cell area. The functional layers are continuous in a main extension plane. An “active cell surface” should preferably be understood to mean a surface area of a functional layer that is actively involved in the combustion process and/or separation process. A "specifically variable layer thickness" should preferably be understood to mean a layer thickness of a functional layer which is intended to be variable in order to achieve a predetermined effect, i.e. has different thicknesses in different partial areas. A deliberately variable layer thickness should in particular not be understood to mean a variable thickness of the layer thickness that is merely caused by manufacturing tolerances. A functional layer with a deliberately variable layer thickness preferably has a different layer thickness, in particular in at least two partial areas. A functional layer with a deliberately variable layer thickness particularly preferably has a different thickness in more than two partial areas. A difference in a thickness of two adjacent partial regions of the functional layer can preferably be only 1 μm, preferably only 0.5 μm. In principle, it is conceivable that a difference in a thickness of two adjacent partial areas of the functional layer is more than 1 μm, more than 5 μm, or more than 15 μm. A layer thickness is to be understood in particular as an extension of a functional layer orthogonal to its main plane of extension.

Due to the configuration of the electrode unit according to the invention, local cell resistances of the functional layers and thus of the entire electrode unit can be set in a targeted manner. The electrical resistance contribution of the individual functional layers depends essentially linearly on the layer thickness of the corresponding functional layer. By adapting the local cell resistances, ie the local electrical resistances of the at least one functional layer, a homogeneous current density distribution over the entire active cell area of the functional layers, ie over the entire active cell area of the electrode unit, can advantageously be achieved. Due to the more uniform utilization of the active cell area of the functional layers of the electrode unit, a higher power density can advantageously be achieved. In a particularly advantageous manner, a lower overall aging rate of the electrode unit can also be achieved, which would otherwise be exacerbated by inhomogeneous operating conditions. As a result, the design according to the invention can increase the service life and thereby reduce the lifetime costs of an electrode unit and the fuel cell and/or electrolyzer unit of which it is a part. Furthermore, it is proposed that the at least one functional layer has a variance in its layer thickness of at least 0.5 μm and a maximum of 20 μm. A “variance in the layer thickness” should preferably be understood to mean a difference in thickness between a thinnest partial area and a thickest partial area of a functional layer. As a result, the at least one functional layer can be equipped with a homogeneous current density distribution in a particularly advantageous manner.

It is further proposed that the at least one functional layer is designed as a partial layer of an electrolyte layer. A “partial layer of an electrolyte layer” should preferably be understood to mean a layer which, together with at least one further partial layer, forms the electrolyte layer which is arranged between the two functional layers designed as electrode layers. The functional layer formed as a partial layer of the electrolyte layer is preferably formed from a doped cerium oxide (CGO/GCO). The functional layer formed as a partial layer of the electrolyte layer is formed as a doped ceran oxide layer. In principle, it is also conceivable that a functional layer formed as a partial layer of an electrolyte layer is formed from a doped zirconium oxide (3YSZ/8YSZ). The functional layer formed as a partial layer of the electrolyte layer is formed as a doped zirconium oxide layer. The electrolyte layer is preferably made up of a partial layer made of a doped cerium oxide (CGO/GCO) and a partial layer made of a doped zirconium oxide (3YSZ/8YSZ). In principle, however, it is also conceivable for the electrolyte layer to be formed from just one layer, or for the electrolyte layer to be formed from more than two partial layers. In principle, it is conceivable that the individual layer or the sub-layers of the electrolyte layer are formed from other materials that appear sensible to a person skilled in the art. The partial layers of the electrolyte layer are preferably formed from a ceramic material. As a result, the functional layer with the variable layer thickness can be formed particularly advantageously in order to achieve a homogeneous current density distribution of the electrode unit.

Furthermore, it is proposed that the at least one functional layer is designed as a diffusion protection layer. A "diffusion protection layer" should preferably be understood to mean a protective layer that is intended to To reduce diffusion processes, preferably to prevent. The functional layer designed as a diffusion protection layer is preferably arranged between a carrier element and a functional layer designed as an electrode layer. The diffusion protection layer is preferably provided to reduce, in particular to prevent, diffusion processes between the carrier element and the functional layer designed as an electrode layer. As a result, the functional layer with the variable layer thickness can be formed in a particularly simple manner in order to achieve a homogeneous current density distribution of the electrode unit.

It is further proposed that the at least one functional layer is designed as an electrode layer. An “electrode layer” should preferably be understood to mean a functional layer that is intended for use as a cathode and/or anode. As a result, one advantageous setting of a homogeneous current density distribution of the electrode unit can be achieved.

Furthermore, it is proposed that several of the functional layers each have a specifically variable layer thickness. “Several functional layers each having a specifically variable layer thickness” should preferably be understood to mean that at least two, preferably three and in a particularly preferred embodiment all functional layers each have a specifically variable layer thickness. As a result, a homogeneous current density distribution of the electrode unit can be achieved particularly well.

Furthermore, it is proposed that the at least one functional layer is produced at least partially by a coating process, in particular by a printing process. A “coating process” should preferably be understood to mean a process with which a material for forming a layer, in particular a functional layer, is applied to a carrier material. The coating process is preferably designed as a printing process. The coating process is particularly preferably designed as an inkjet printing process. In principle, it is also conceivable that the coating process is in the form of a spraying or gas phase deposition process. In principle, it is also conceivable that the coating process drive is designed as a screen printing process. As a result, the functional layer can be formed particularly simply and advantageously with a variable layer thickness.

In addition, a method for producing an electrode unit for a preferably supported, in particular metal-supported, fuel cell and/or electrolyzer unit, in particular solid oxide fuel cell unit, is proposed, wherein at least one functional layer is applied in at least one method step, wherein the functional layer is different in different partial areas in the at least one method step is applied thickly. “Applied” is to be understood as meaning applied in layers to a carrier material, preferably by means of a suitable coating process. As a result, an advantageous method for producing an electrode unit with an advantageously homogeneous current density distribution can be provided.

It is further proposed that in the at least one method step the at least one functional layer is applied in partial areas of different thicknesses by means of a p-inkjet method. A “p-inkjet method” should preferably be understood to mean a printing method, in particular an inkjet printing method, in which a material for layer formation can be applied to a carrier material via a plurality of print nozzles that can be controlled in a targeted manner. In the p-inkjet process, a layer is preferably applied to a carrier material via a plurality of printing nozzles arranged in parallel. In the p-inkjet process, a layer with a layer thickness of less than 1 μm, preferably 0.5 μm, can be applied. In the p-inkjet method, a layer with a variance in the layer thickness of two adjacent partial regions of less than 1 μm, preferably 0.5 μm, can be applied to a carrier material. A layer, in particular a functional layer, can be applied to a carrier material by means of the p-inkjet method, which layer has two adjacent partial regions with a thickness difference of less than 1 μm, preferably 0.5 μm. As a result, the functional layer can be produced in a particularly simple manner and with an advantageously small difference in thickness between adjacent partial regions. As a result, a current density distribution of a functional layer over its entire active cell surface can be adjusted particularly finely. As a result, a particularly homogeneous current density distribution of the electrode unit can be achieved.

In addition, it is proposed that in the at least one method step the at least one functional layer is applied by means of a plurality of pressure nozzles that are controlled in a targeted manner. A “specifically controlled print nozzle” should preferably be understood to mean a print nozzle of an inkjet printer for a p-inkjet process, which can finely meter a delivery quantity for producing a layer via a specific electrical and/or electronic control. The pressure nozzles that can be controlled in a targeted manner are preferably arranged parallel to one another. As a result, the at least one functional layer can be produced particularly advantageously.

It is also proposed that in the at least one method step, the several selectively controllable pressure nozzles for generating the partial areas of different thicknesses are controlled with different parting parameters, such as in particular a different pulse strength and/or a different frequency. A “deposition parameter” should preferably be understood as a control parameter by means of which a pressure nozzle that can be controlled in a targeted manner is controlled and, as a result of the corresponding control, the pressure nozzle releases a defined quantity of material to form a layer, in particular a functional layer. As a result, a printing process of the at least one functional layer can take place particularly advantageously.

Furthermore, a fuel cell, in particular a solid oxide fuel cell, is proposed with at least one fuel cell and/or electrolyzer unit with at least one electrode unit.

The method according to the invention, the electrode unit according to the invention and/or the fuel cell according to the invention should not be limited to the application and embodiment described above. In particular, the method according to the invention, the carrier according to the invention and/or the fuel cell according to the invention can deviate from a number of individual elements, components and units as well as method steps mentioned herein in order to fulfill a function described herein. corresponding number. In addition, in the value ranges specified in this disclosure, values lying within the specified limits should also be considered disclosed and can be used as desired.

drawings

Further advantages result from the following description of the drawing. Two exemplary embodiments of the invention are shown in the drawings. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into further meaningful combinations.

Show it:

1 shows a schematic sectional view through an electrode unit of a fuel cell and/or electrolyzer unit with a functional layer with a specifically variable layer thickness in a first exemplary embodiment,

2 shows a schematic representation of a pressure nozzle in a method according to the invention for producing a functional layer with the deliberately variable layer thickness in a schematic representation,

3 shows a schematic view of a division of partial areas with different layer thicknesses of the functional layer for an electrode device in a cross-flow arrangement,

4 shows a schematic view of a division of partial areas with different layer thicknesses of the functional layer for an electrode device in a co-flow arrangement,

5 shows a schematic view of a division of partial areas with different layer thicknesses of the functional layer for an electrode device in a counterflow arrangement,

6 shows a method according to the invention for producing an electrode unit and 7 shows a schematic sectional view through an electrode unit of a fuel cell and/or electrolyzer unit with a functional layer with a specifically variable layer thickness in a second exemplary embodiment.

Description of the exemplary embodiments

FIG. 1 shows part of a fuel cell and/or electrolyzer unit 10a, in particular a solid oxide fuel cell unit. The supported, in particular metal-supported, fuel cell and/or electrolyzer unit 10a comprises an electrode unit 12a. The electrode unit 12a includes a carrier element 24a. The carrier element 24a forms a basic structure of the electrode unit 12a. The carrier element 24a preferably has a porous structure.

The electrode unit 12a has a plurality of functional layers 14a, 16a, 18a, 20a, 22a. The functional layers 14a, 16a, 18a, 20a, 22a are applied in layers to the carrier element 24a. The functional layers 14a, 16a, 18a, 20a, 22a are arranged in layers one above the other on the carrier element 24a. The electrode unit 12a preferably has five functional layers 14a, 16a, 18a, 20a, 22a. Two of the functional layers 14a, 20a of the electrode unit are designed as electrode layers, in particular for use as a cathode and/or anode. The functional layer 14a is designed as a cathode. The functional layer 14a is designed as an oxidant electrode, in particular for contact with the oxidant and/or a cleavage product. The functional layer 20a is designed as an anode. The functional layer 20a is designed as a fuel electrode, in particular for contact with the fuel and/or another fission product.

The functional layer 22a is designed as a diffusion protection layer. The functional layer 22a embodied as a diffusion protection layer is arranged between the carrier element 24a and the functional layer 20a embodied as an electrode layer. The functional layer 22a designed as a diffusion protection layer is provided to protect against undesired diffusion processes. The functional layer 22a designed as a diffusion protection layer prevents a diffusion sion between the functional layer 20a designed as an electrode layer and the carrier element 24a.

The functional layer 16a is formed as a partial layer of an electrolyte layer. The functional layer 18a is a partial layer of the electrolyte layer. The two functional layers 16a, 18a together form the electrolyte layer. The electrolyte layer is arranged between the two functional layers 14a, 20a designed as an electrode layer. The electrolyte layer is designed in particular as a separating layer for the functional layers 14a, 20a designed as an electrode layer. The two functional layers 16a, 18a arranged as a partial layer of the electrolyte layer are formed between the functional layers 14a, 20a formed as electrode layers. The functional layer 18a formed as a partial layer of the electrolyte layer is formed from a doped zirconium oxide (8YSZ (ZrO2 fully stabilized with yttrium oxide)). In principle, it is also conceivable that the functional layer 18a, which is designed as a partial layer of the electrolyte layer, is formed from another electrolyte that appears sensible to a person skilled in the art. The functional layer 16a formed as a partial layer of the electrolyte layer is formed from a doped cerium oxide (CGO).

The functional layer 16a, which is designed as a partial layer of the electrolyte layer, has a specifically variable layer thickness 26a over its active cell area. The functional layer 16a formed as a partial layer of the electrolyte layer is produced by a coating method, in particular by a printing method. An electrical resistance contribution of an individual functional layer 16a depends essentially linearly on the layer thickness of the functional layer 16a. The purposefully variable layer thickness 26a of the functional layer 16a allows a current density distribution of the functional layer 16a and thereby a current density distribution of the entire electrode unit 12a to be adjusted by locally adjusting the resistance contribution of individual partial areas of the functional layer 16a. Functional layer 16a, which is designed as a sublayer of the electrolyte layer, has a plurality of subregions 28a, 30a, 32a, 34a, 36a. The functional layer 16a designed as a partial layer of the electrolyte layer has, for example, thirteen partial regions 28a, 30a, 32a, 34a, 36a, of which only five have been given a reference number for reasons of clarity. The as part of the Electrolyte layer formed functional layer 16a has in the different partial areas 28a, 30a, 32a, 34a, 36a in each case at least to the adjacent partial area 28a, 30a, 32a, 34a, 36a different layer thicknesses 26a. The partial areas 28a, 30a, 32a, 34a, 36a of the functional layer 16a all have a different layer thickness 26a. In principle, it would also be conceivable for two non-adjacent partial regions 28a, 30a, 32a, 34a, 36a of the functional layer 16a to have the same layer thickness 26a. The functional layer 16a formed as a partial layer of the electrolyte layer has a variance in the layer thickness 26a of 5 μm. The functional layer 16a has a maximum layer thickness 26a in one partial region 36a. In the case of a functional layer with a constant layer thickness (prior art), partial region 36a would have had the highest current density. The partial area 28a of the functional layer 16a has the smallest layer thickness 26a. In the case of a functional layer with a constant layer thickness (prior art), the partial region 28a would have had the lowest current density. The further partial areas 30a, 32a, 34a each have a layer thickness 26a which lies between the maximum layer thickness 26a of the partial area 36a and the minimum layer thickness 26a of the partial area 28a. The arrangement and the size of the partial areas 28a, 30a, 32a, 34a, 36a is selected as an example. An arrangement, a size and the respective layer thickness 26a in the different partial regions 28a, 30a, 32a, 34a, 36a of a functional layer 16a depend in particular on a shape of the electrode unit 12a and an inflow direction of a fuel and a fission product.

By way of example, FIG. 3 shows a division of the partial regions 28a, 30a, 32a, 34a, 36a with different layer thicknesses 26a of a functional layer 16a designed as a partial layer of an electrolyte layer for an electrode device 12a in a cross-flow arrangement, in which a fuel and a fission product are conducted into the electrode device 12a from two sides which are at a 90 degree angle to one another. Figure 4 shows an example of a division of the partial areas 28a, 30a, 32a, 34a, 36a with different layer thicknesses of a functional layer 16a designed as a partial layer of an electrolyte layer for an electrode device 12a in a co-flow arrangement, in which a fuel and a fission product from the same Page are passed into the electrode device 12a. FIG. 5 shows, by way of example, a division of the partial regions 28a, 30a, 32a, 34a, 36a with different layer thicknesses as a partial layer a functional layer 16a formed with an electrolyte layer for an electrode device 12a in a counterflow arrangement, in which a fuel and a fission product are conducted into the electrode device 12a from opposite sides.

A method according to the invention for producing the electrode unit 12a for the supported, in particular metal-supported, fuel cell and/or electrolyzer unit 10a will be briefly described below. In a method step 42a, the functional layer 22a embodied as a diffusion protection layer is first applied to the carrier element 24a. The functional layer 22a designed as a diffusion protection layer is applied to the carrier element 24a by means of a coating process. The functional layer 22a formed as a diffusion protection layer is applied to the carrier element 24a by means of a printing process.

In a further method step 44a, the functional layer 20a embodied as an electrode layer is applied to the functional layer 22a embodied as a diffusion protection layer. The functional layer 20a embodied as an electrode layer is applied to the electrode unit 12a, in particular the functional layer 22a embodied as a diffusion protection layer, using a coating method, in particular by means of a printing method.

In a further method step 46a, the functional layer 18a embodied as a partial layer of the electrolyte layer is applied to the functional layer 20a embodied as the electrode layer. The functional layer 18a embodied as a partial layer of the electrolyte layer is applied to the electrode unit 12a, in particular to the functional layer 20a embodied as an electrode layer, by a coating method, in particular by means of a printing method.

In a further method step 48a, the functional layer 16a, which has a deliberately variable layer thickness 26a over its active cell area, is applied. The functional layer 16a, which is designed as a partial layer of the electrolyte layer, is applied with different thicknesses in the different partial regions 28a, 30a, 32a, 34a, 36a in the method step 48a. Due to the different Lich thick applications of the functional layer 16a in the different sub-areas 28a, 30a, 32a, 34a, 36a, these each have a different layer thickness. The functional layer 16a is applied in method step 48 by means of a p-inkjet method. The functional layer 16a can be applied in the different partial areas 28a, 30a, 32a, 34a, 36a with a variance between two adjacent partial areas 28a, 30a, 32a, 34a, 36a of 0.5 μm by means of the p-inkjet method.

In method step 48a, the functional layer 16a is applied by means of a plurality of pressure nozzles 38a that can be controlled in a targeted manner. FIG. 2 shows an example of a pressure nozzle that can be controlled in a targeted manner during method step 48a for printing functional layer 16a. The functional layer 16a is applied by means of a plurality of pressure nozzles 38a, preferably arranged in parallel, in a CNC-controlled printing process. The pressure nozzles 38a that can be controlled in a targeted manner are controlled with different control parameters in order to generate the partial regions 28a, 30a, 32a, 34a, 36a of different thicknesses. The control parameters are designed in particular as a frequency and a pulse strength of the control signal of the pressure nozzles 38a. The pressure nozzles 38a each have a piezoelectric signal generator 40a, which regulates a flow through the respective pressure nozzle 38a. By changing the control parameters, the size of the released droplets of a material that forms the functional layer 16a, and thus the layer thickness 26a, can be set with an accuracy of 0.5 μm (see FIG. 2). A layer thickness of the functional layer 16a that can be set precisely to 0.5 μm can be set by the pressure nozzles that can be controlled in a targeted manner. Due to the pressure nozzles 38a arranged in parallel, a different thickness 36a of the functional layer 16a can be applied in different partial areas 28a, 30a, 32a, 34a, 36a in the method step 48a.

Alternatively, it is also conceivable that the different layer thicknesses in the partial areas 28a, 30a, 32a, 34a, 36a are achieved by multiple coating in the thicker partial areas 28a, 30a, 32a, 34a, 36a in several printing process steps. Basically, it is also conceivable that the functional layer 16a with its variable layer thickness by a spray or gas phase senabscheideverfahren is realized in several coating processes with different masks.

In a further method step 50a, the functional layer 14a embodied as an electrode layer is applied to the functional layer 16a. The functional layer 14a embodied as an electrode layer is applied to the functional layer 16a embodied in the electrode unit 12a, in particular the partial layer of the electrolyte layer, using a coating method, in particular by means of a printing method. All functional layers are preferably applied to the electrode unit 12a using the same coating method, in particular using the p-inkjet method. In principle, however, it is also conceivable that different coating methods are used to apply the different functional layers.

Another exemplary embodiment of the invention is shown in FIG. The following descriptions and the drawings are essentially limited to the differences between the exemplary embodiments, whereby with regard to components with the same designation, in particular with regard to components with the same reference numbers, the drawings and/or the description of the other exemplary embodiments, in particular Figures 1 to 6, can be referred. To distinguish between the exemplary embodiments, the letter a follows the reference number of the exemplary embodiment in FIGS. In the exemplary embodiments of FIG. 7, the letter a has been replaced by the letters b.

FIG. 7 shows part of a fuel cell and/or electrolyzer unit 10b, in particular a solid oxide fuel cell unit. The supported, in particular metal-supported, fuel cell and/or electrolyzer unit 10b comprises an electrode unit 12b. The electrode unit 12b includes a carrier element 24b. The carrier element 24b forms a basic structure of the electrode unit 12b. The carrier element 24b preferably has a porous structure.

The electrode unit 12b has several functional layers 14b, 16b, 18b, 20b, 22b. The functional layers 14b, 16b, 18b, 20b, 22b are on the carrier ger element 24b applied in layers. The functional layers 14b, 16b, 18b, 20b, 22b are arranged in layers one above the other on the carrier element 24b. Two of the functional layers 14b, 20b of the electrode unit 12b are designed as electrode layers, in particular for use as a cathode and/or anode. The functional layer 14b is designed as a cathode. The functional layer 14b is designed as an oxidant electrode, in particular for contact with the oxidant and/or a cleavage product. The functional layer 20b is designed as an anode. The functional layer 20b is designed as a fuel electrode, in particular for contact with the fuel and/or another fission product.

The functional layer 22b is designed as a diffusion protection layer. The functional layer 22b designed as a diffusion protection layer is arranged between the carrier element 24b and the functional layer 20b designed as an electrode layer.

The functional layer 16b is designed as a partial layer of an electrolyte layer. The functional layer 18b is a partial layer of the electrolyte layer. The two functional layers 16b, 18b together form the electrolyte layer. The electrolyte layer is arranged between the two functional layers 14b, 20b designed as an electrode layer.

In contrast to the first exemplary embodiment, several of the functional layers 14b, 16b, 18b, 20b, 22b have a layer thickness 36b that is specifically variable over their active cell area. All functional layers of the electrode unit 12b have a specifically variable layer thickness 36b over their active cell area. The functional layer 22b designed as a diffusion protection layer has a variable layer thickness 52b over its active cell area. FIG. 7 shows, by way of example, different partial areas of the functional layer 22b designed as a diffusion protection layer, each of which has a different layer thickness 52b. The functional layer 22b designed as a diffusion protection layer preferably has a variance of 5 μm in its layer thickness 52b. The functional layer 20b designed as an electrode layer has a variable layer thickness 54b over its active cell area. FIG. 7 shows, by way of example, different partial areas of the functional layer 20b designed as an electrode layer, which each have a different layer thickness 54b. The functional layer 20b designed as an electrode layer preferably has a variance of 10 μm in its layer thickness 54b.

Functional layer 18b, which is designed as a partial layer of the electrolyte layer, has a variable layer thickness 56b over its active cell area. FIG. 7 shows, by way of example, different partial areas of the functional layer 18b, which is designed as a partial layer of the electrolyte layer, each having a different layer thickness 56b. The functional layer 18b, which is designed as a partial layer of the electrolyte layer, preferably has a variance of 10 μm in its layer thickness 56b. As already described in the first exemplary embodiment, the functional layer 16b embodied as a partial layer of the electrolyte layer has a specifically variable layer thickness 26b.

The functional layer 14b designed as an electrode layer has a variable layer thickness 58b over its active cell area. FIG. 7 shows, by way of example, different partial areas of the functional layer 14b designed as an electrode layer, which each have a different layer thickness 58b. The functional layer 14b designed as an electrode layer preferably has a variance of 10 μm in its layer thickness 58b.

As in the first exemplary embodiment, the functional layers 14b, 16b, 18b, 20b, 22b are applied to the carrier element 24b by a suitable coating method. Because all functional layers 14b, 16b, 18b, 20b, 22b have a specifically variable layer thickness 28b, 52b, 54b, 56b, 58b, a local resistance contribution of the individual functional layers 14b, 16b, 18b, 20b, 22b and thus the local electrical Resistance of the electrode unit 12b can be set particularly precisely over the active cell area. As a result, an electrode unit 12b with a particularly homogeneous current density distribution can be provided. In order to save costs, it would basically also be conceivable to form only two or only three of the functional layers 14b, 16b, 18b, 20b, 22b with a purposefully variable layer thickness 28b, 52b, 54b, 56b, 58b.

Claims

Expectations

1. Electrode unit for a preferably supported, in particular metal-supported, fuel cell and/or electrolyzer unit (10a; 10b), in particular solid oxide fuel cell unit, which has a plurality of functional layers (14a, 16a, 18a, 20a, 22a; 14b, 16b, 18b, 20b , 22b), characterized in that at least one of the functional layers (16a; 14b, 16b, 18b, 20b, 22b) has a specifically variable layer thickness (26a; 26b, 52b, 54b, 56b, 58b) over its active cell area.

2. Electrode unit according to claim 1, characterized in that the at least one functional layer (16a; 14b, 16b, 18b, 20b, 22b) has a variance in its layer thickness (26a; 26b, 52b, 54b, 56b, 58b) of at least 0, 5pm and a maximum of 20pm.

3. Electrode unit according to claim 1 or 2, characterized in that the at least one functional layer (16a; 16b) is designed as a partial layer of an electrolyte layer,

4. Electrode unit according to one of the preceding claims, characterized in that the at least one functional layer (22b) is designed as a diffusion protection layer.

5. Electrode unit according to one of the preceding claims, characterized in that the at least one functional layer (14b, 20b) is designed as an electrode layer.

6. Electrode unit according to one of the preceding claims, characterized in that several of the functional layers (14b, 16b, 18b, 20b, 22b) each have a specifically variable layer thickness (26b, 52b, 54b, 56b, 58b). Electrode unit according to one of the preceding claims, characterized in that the at least one functional layer (16a; 14b, 16b, 18b, 20b, 22b) is produced at least partially by a coating process, in particular by a printing process. Method for producing an electrode unit (12a; 12b) for a preferably supported, in particular metal-supported, fuel cell and/or electrolyzer unit (10a), in particular solid oxide fuel cell unit, according to one of claims 1 to 5, wherein in at least one method step at least one functional layer ( 42a, 44a, 46a, 48a, 50a) is applied, characterized in that in the at least one method step (48a) the functional layer (16a; 14b, 16b, 18b, 20b, 22b) is applied in different partial areas (30a, 32a, 34a, 36a) is applied with different thicknesses. Method according to Claim 6, characterized in that in the at least one method step (48a) the at least one functional layer (16a; 14b, 16b, 18b, 20b, 22b) in partial regions (30a, 32a, 34a, 36a) of different thicknesses by means of a p inkjet process is applied. Method according to Claim 6 or 7, characterized in that in the at least one method step (48a) the at least one functional layer (16a; 14b, 16b, 18b, 20b, 22b) is applied by means of a plurality of pressure nozzles (38a) that are controlled in a targeted manner. Method according to Claim 8, characterized in that in the at least one method step (48a) the plurality of pressure nozzles (38a) which can be controlled in a targeted manner for generating the sub-areas (30a, 32a, 34a, 36a) of different thicknesses are used with different parting parameters, such as in particular a different pulse strength and /or a different frequency. Fuel cell and/or electrolyzer unit, in particular solid oxide fuel cell, with at least one electrode unit (12) according to one of Claims 1 to 7.