DE10317976B4 - Solid electrolyte fuel cell and method for its production and use of the solid electrolyte fuel cell as an electrolyzer - Google Patents

Abstract

Solid electrolyte fuel cell having a serving as an anode functional layer and serving as a cathode functional layer, which are separated by a Separator- or electrolyte layer, wherein the functional layers are electrochemically active and a gas inlet and a gas outlet are present, wherein the gases to be reacted from the gas inlet to the gas outlet the respective functional layer overflow along a predetermined flow direction, characterized in that the electrochemical activity and the ionic conductivity of at least one functional layer is graduated over the surface of the functional layer in such a way that the electrochemical activity and the ionic conductivity from the gas inlet (3) to the gas outlet (4) changed along the flow direction (2).

Description

The invention relates to a solid electrolyte fuel cell according to the preamble of claim 1 and to a method for producing the solid electrolyte fuel cell according to the preamble of claim 10.

The solid electrolyte fuel cell belongs to the so-called high-temperature fuel cells. The solid oxide fuel cell (hereinafter abbreviated to SOFC) takes its name from its solid as opposed to "liquid" - oxide ceramic electrolyte. This electrolyte layer separates the anode from the cathode as a separator. The operating temperature of an SOFC is between 650 and 1000 ° C. The anode and cathode have many open pores for good flow through to provide a large surface for the chemical reaction inside the reaction gases (eg, hydrogen and oxygen). A typical SOFC cathode usually consists of a ceramic mixed oxide with perovskite structure (eg ceramic lanthanum-strontium-manganese oxide (LSM), which can also be mixed with electrolyte material.) This cathode is in contact with the thin electrolyte ceramic, which consists of, for example Yttrium-stabilized zirconium oxide (YSZ) is a porous cathode that allows the air to flow through it like a sponge, and the gaseous oxygen is decomposed into its atoms on the large surface inside the cathode in an electrochemical reaction The oxygen ions migrate through the electrolyte to the anode side of the cell, while the hydrogen protons remain bound to the anode, thanks to the electrolyte, which acts as the separator in the SOFC the oxygen ions permeable, they flow through it through to the anode and react there with the protons to water. In the region in which the particles of the porous cathode material are in contact with the electrolyte, the oxygen ions can enter the electrolyte. In order to get into the electrolyte, each oxygen atom needs extra electrons. This provides the cathode. They come from the anode, where they have split off from the hydrogen atoms. From there they flow as a transporter of electrical energy from the fuel cell via electrical lines to a consumer. In the consumer they convert a large part of the transported energy into useful work. Then they flow back to the fuel cell in the cathode, where they are now the oxygen available for its reduction.

High-temperature fuel cell assemblies and methods of applying layers are disclosed in U.S. Patent Nos. 5,496,066 DE 3907485 A1 described. One of the common methods of applying layers to a substrate, particularly yttria-stabilized zirconia, is plasma spraying. In plasma spraying, a powder is melted in a plasma generated by an arc and injected at high speed onto a substrate, where the material solidifies as a layer.

From the DE 4122942 C1 is a method for producing a powder, which is provided as a plasma spray powder for the production of a fuel cell anode on a ceramic substrate, in particular an yttrium-stabilized zirconium oxide electrolyte disk known. Here, from certain starting substances by wet milling and subsequent drying and precalcining and subsequent coarse and fine comminution a spray powder in the particle size range of about 30-90 microns is produced, which can then be sprayed.

From "Fabrication of the Electrolyte-Electrodes Assembly by Applying the Vacuum Plasma Spraying Technology"; G. Schiller, R. Henne and M. Lang; 3. European Solid Oxide Fuel Cell Forum, Nantes, 2-5.06.1998, it is known that plasma spraying under vacuum opens the possibility of producing the complete multi-layered electrode assembly in a rapid multistage injection process. The production by plasma spraying requires a modified planar cell design, which is adapted to the characteristics of spraying. The development is based on a porous support substrate and thin electrodes and electrolyte layers which are applied sequentially. The plasma spraying process used allows the deposition of very thin but dense electrolyte layers as well as porous electrode layers with thickness-graded composition and porosity.

From the WO 02/084774 A2 For example, a multi-layer and multi-functional cathode for SOFC is known which is said to have high conductivity, high catalytic activity, excellent compatibility with other areas of a fuel cell and suitability for reduced working temperature. The cathode comprises a conductive layer, a catalytic layer and a graded composite layer. The conductive layer has a first density, the catalytic layer has a second density which is less than the first density, and the graded composition layer is characterized in that the electron conductivity and the ionic conductivity are graded across the layer thickness. The electron conductivity should be from a lower side of the layer to an upper side of the composite layer rise to the graded layer, wherein the underside is the surface which is immediately adjacent to the catalytic layer. In contrast, the ionic conductivity should preferably decrease from the lower layer to the surface. On the surface, the layer should be 70-100% electron conductor, while in the ground area 50-70% ion conductivity should be present. The grading is achieved by bringing several layers together by spraying, casting or laminating or deposition.

From the WO 97/41612 A1 It is known to layer layers with different functionality, matched to the oxygen partial pressure in a cell to each other, in which case a functional grading is to be achieved according to the chemical properties. As in the other prior art also, the ceramic reaction layers anode and cathode are graded and stabilized in the thickness direction with reaction-promoting rare earth metals.

From the JP 06342663 A For example, a solid electrolyte fuel cell is known in which the electrochemical activity of a functional layer is graduated by varying the thickness of an electrode. The electrochemical properties of the electrode material are not varied.

In the DE 195 19 847 C1 For example, there is described an anode substrate for a methane-steam reforming reaction of a high-temperature fuel cell, in which the anode substrate has regions near channels in which the catalyst concentration is lowered and thus has a reduced activity for the reforming reaction.

From the DE 692 03 650 T2 For example, a method for producing a solid oxide film and methods for producing a solid oxide fuel cell using the solid oxide film is known. In particular, it is described to produce a solid oxide layer with improved airtightness by means of a heat treatment.

In the known SOFC has the disadvantage that they are not optimal in terms of efficiency and destruction by thermally induced voltages can occur.

The object of the invention is to provide a solid electrolyte fuel cell, which has a higher efficiency than known solid electrolyte fuel cells and greatly reduced in the thermally induced mechanical stresses.

This object is achieved with a solid electrolyte fuel cell with the features of claim 1.

Advantageous developments are characterized in the dependent claims.

It is a further object to provide a method for producing a solid electrolyte fuel cell having reduced thermally induced mechanical stresses and higher efficiency, in particular according to claim 1. The object is achieved by a method having the features of claim 10.

Further advantageous embodiments are characterized in the dependent claims.

Due to the series connection of many fuel cells to form a fuel cell block, the electrodes of the individual cells must be flowed parallel to their surface with the fuel gas required for power generation. As fuel gases can hydrogen, methanol, natural gas or reformates of higher hydrocarbons such. As gasoline, diesel or kerosene are used. On the anode side, there is a depletion of the combustible components (reactants) in the fuel gas between the fuel gas inlet and outlet along the anode surface. The reactants diffuse from the fuel gas flow in the anode layer, where they are converted by electrochemical reaction and released as exhaust gases back into the gas stream. The concentration of the reactants contained in the fuel gas and utilizable by the fuel cells thus decreases along the cell surface. Since the local electric power production of the fuel cell is proportional to the number of electrochemical reactions, depletion of the combustible components of the fuel gas causes the electric power production of the fuel cell not to be equal over its entire area but decreases in gas flow direction from the fuel gas inlet to the exit ,

According to the invention, it has been recognized that the electricity generation potential of those fuel cell areas which are closer to the gas outlet can not be used optimally for energy conversion, if the cell areas at the gas inlet are not to be electrically overloaded.

Especially with the SOFC, the electricity generation takes place only from a certain response temperature and increases with increasing temperature. According to the invention, it has been recognized that a temperature gradient is formed during the heating process and during operation. Warmer cell areas thus reach the response temperature sooner and generate electricity earlier than colder cell areas. Since energy production also generates energy loss in the form of heat, the warm area heats up further, which promotes even higher electricity production. According to the invention, it has been recognized that these temperature gradients resulting from the heating process can lead to damage of the SOFC by thermally induced mechanical stresses.

According to the invention, the problems identified by the inventors are eliminated by specifically locally influencing the electrochemical properties of the fuel cells or the layers of the fuel cells along the flow direction of the reactants. According to the invention, in the areas of the SOFC in which a high fuel gas supply and high temperatures prevail during the heating operation, a smaller amount of ion-conductive material is applied or there is less nickel in the anode. Along the fuel gas flow direction, the proportion of the better ion-conductive material increases continuously in relation to the temperature gradient.

The method provides for at least one of the functional layers to be formed from a base material and at least one doping element influencing the electrochemical activity, wherein the electrochemical activity of the operational functional layer via a gas flow direction (FIG. 2 ) is changed in that a concentration gradient of the at least one doping element via the flow direction ( 2 ) is generated, so that during the application of an enrichment or depletion of the at least one doping element is made.

In particular, for the enrichment and depletion of the respective doping element, the mixing ratio of at least two components is changed for the same application volume, wherein a first component of the mixture contains the base material and at least a first doping element and a second component of the mixture contains the base material and at least one second doping element.

In this case, it is advantageous that increased ionic conductivity in the region of lower fuel gas supply (toward the fuel gas outlet) and lower cell temperature leads to a homogenization of the electricity generation over the cell surface and to a simultaneous onset of electricity generation over the cell surface during the starting process of the SOFC. This makes it possible to achieve a maximum of electricity yield with a minimum of cell area and in particular of material use. A reduction in the cell area is also followed by a reduction in the volume and mass of the fuel cell stack, with consequent savings in the housing.

The method according to the invention provides for applying different ion-conducting or differently thick SOFC materials via plasma spraying, wherein the total quantity and / or the composition of the material to be sprayed on, ie in particular of a powder, is changed continuously or graduated during the spraying process.

As a result, a gradation of the material composition and / or material thickness and thus also of the properties along the flow direction and / or the application direction of the plasma torch can be achieved.

The invention will be explained by way of example with reference to a drawing. Hereby show:

1 schematically a plan view of a functional layer of a SOFC from the fuel gas inlet to the fuel gas outlet;

2 schematically a plan view of a functional layer of a SOFC with a registered movement of a plasma torch during the manufacturing process;

3 a functional layer after 2 wherein a further direction of movement of the plasma torch is shown during the manufacturing process.

1 shows in simplified form a plan view of an anode surface of a solid electrolyte fuel cell 1 , Along a flow direction 2 a suitable fuel gas flows from a fuel gas inlet side 3 to a fuel gas outlet side 4 , As fuel gases can be hydrogen, methanol, natural gas or reformate higher hydrocarbons such. As gasoline, diesel or kerosene are used. About the flow direction 2 depletes the fuel gas to reactants and is enriched with reaction products. There is thus a richer in reactants area 5 and an area poorer in reactants 6 ,

In order to equalize the electric current density and the fuel cell temperature according to the invention along the flow direction 2 to generate, the local ion conductivity of the electrolyte or the nickel concentration in the anode of the solid electrolyte fuel cell along the flow direction 2 changed. For example For example, yttria-stabilized zirconia (YSC) has lower ionic conductivity and higher response temperature than scandium-stabilized zirconia. The same applies, however, to different stoichiometric compositions of yttrium and zirconium oxide. These materials are not only the constituents of the electrolyte of the SOFC, but they are also present in the anode and, ideally, also in the cathode of the SOFC. The composition of the ion conductor, the relative content of the ion conductor in the anode and cathode and the thicknesses of the ion-conducting layers thus influence all the electrochemically active layers of the SOFC. According to the invention, the ionic conductivity of the fuel gas inlet 3 to the exhaust outlet 4 and / or increased from the warmer to the colder region of the fuel cell. The increase in this case can be continuous or gradual continuously, wherein the gradations may be present with the same or different composition differences. The concentration gradient between the input side 3 and home page 4 may be performed linearly according to a straight line or nonlinear corresponding to, for example, a parabola or hyperbola. With a non-linear gradation, for example, the flow behavior of the fuel gas, such. B. the formation of boundary layers and thus both the diffusion and heat transfer behavior to the fuel gas are taken into account.

In principle, a less ion-conductive material is applied in the regions of the SOFC in which a high fuel gas supply and / or high temperatures prevail during the heating operation later during operation. In the course of the fuel gas flow direction 2 then the proportion of the better ionic conductive material increases according to the upper specification.

The inventive method provides to apply the graded functional layer by means of plasma spraying. In this process, the powdery starting materials of the solid electrolyte fuel cell are fed to a burner, melted in an ionized gas flow (plasma), greatly accelerated and applied to the carrier material (substrate). In this case, a plasma torch, similar to a spray gun, is guided meander-shaped over the substrate. In this way, layer by layer first the anode, then the electrolyte and finally the cathode realized. According to the invention, two materials having the same function but different properties, in particular ion conductivity properties, are deposited at suitable regions of the SOFC. According to the method of the invention, this takes place in a particularly simple but highly effective manner in that the type and quantity of the material transported to the plasma torch and then sprayed on is determined by regulating the material supply. According to the invention, a powder feed device with at least two separate powder conveying systems, each with a different ion-conducting powder, is connected to the plasma torch. During the method of the burner, a control device controls the powder feed device and in particular the powder delivery systems in such a way that the material composition within the individual SOFC layers, in particular the electrode layers, targeted over the subsequent flow direction 2 of a fuel gas is affected.

Will, as in 2 shown, the burner so moved that the meander 7 run perpendicular to the fuel gas flow direction, the composition during a movement of the burner is transverse to the later fuel gas flow direction 2 kept constant and in the process of the burner with or against the flow direction - depending on the movement of the burner - the powder delivery systems influenced so that the amount (delivery rate) of the one powder is increased at the expense of the amount (delivery rate) of the other powder or vice versa. As a result, in the areas of the SOFC in which a high fuel gas supply and / or high temperatures prevail during operation during the heating operation, the less ion-conductive material can be more strongly metered in and applied.

In a further advantageous embodiment of the method, the burner is parallel with or against the later flow direction 2 method, wherein in the promotion of the aufzuspritzenden powder, the powder amount of a material during the movement of the burner over the substrate is increased continuously or stepped at the expense of the other material. After the burner has traveled over the substrate, it can perform a lateral displacement movement and perform a reverse movement against the first direction of movement carried out, in which the first sprayed process runs backwards, ie, that the material that was depleted during the first injection process, now during the Injection movement in the opposite direction is enriched again accordingly. This process is carried out accordingly until the complete substrate is coated according to the requirements.

In a further advantageous embodiment, the burner movement takes place with simultaneous spraying only in one direction, for example only in the direction of flow, so that the control is carried out so that the higher ion-conductive material is initially added less and the addition or the proportion during the crossing of the substrate continuously or gradually increases. After passing over the substrate of the plasma torch performs a return movement, at the same time the dosage is controlled such that after completion of the return movement is again started with a high concentration of the less ion-conductive material.

In a further advantageous embodiment of the method according to the invention, in addition to the gradation along the flow direction, a gradation in the thickness direction takes place, so that after the substrate has once been completely covered with a layer, a next thin layer of the same function, for example an anode function, is applied, in which already the starting composition to the starting composition of the underlying layer is another, that is, for example, higher or lower ionic conductivity. This can be done, for example, by enriching one of the two powdered substances at the expense of the other or by adding a third substance if desired. In this case, of course, the third substance may also be a mixture of a plurality of substances, which is either finished fed to the burner or mixed in the same manner as the first two substances only in the region of the burner head by a powder delivery system.

According to the invention, it has been found that plasma spraying is particularly suitable for achieving the gradation according to the invention along the flow direction. With appropriate effort, the gradation according to the invention along the flow direction but also with other application methods can be realized, for example, with appropriately trained thin film (foil) casting process.

In an inventive SOFC with a grading of the ionic conductivity along the flow direction of the fuel gases, it is advantageous that this leads to a homogenization of the electricity generation over the cell surface and to a simultaneous onset of electricity generation over the cell surface during the SOFC start-up program. This makes it possible to achieve a maximum of electricity yield with a minimum cell area or material use. As a result, the total cost of the SOFC, in particular by reducing the volume and mass of the fuel cell stack and thus a reduction of the housing and the insulation are achieved.

In the method according to the invention, it is advantageous that the grading according to the invention is achieved in a particularly simple and effective manner both in the longitudinal direction, ie. H. can be achieved in the gas flow direction, as well as in the thickness direction.

The invention is in no way limited to grading only the anode surfaces or the anode layer along the flow direction, grading can also be achieved in other functional layers.

The invention is also not limited to a fuel cell. It can be used with equal success and advantage in an electrolyzer, the chemical reversal of a fuel cell.

Claims (24)

Solid electrolyte fuel cell having a serving as an anode functional layer and serving as a cathode functional layer, which are separated by a Separator- or electrolyte layer, wherein the functional layers are electrochemically active and a gas inlet and a gas outlet are present, wherein the gases to be reacted from the gas inlet to the gas outlet the respective functional layer overflow along a predetermined flow direction, characterized in that the electrochemical activity and the ionic conductivity of at least one functional layer over the surface of the functional layer is graduated such that the electrochemical activity and the ionic conductivity of the gas inlet ( 3 ) to the gas outlet ( 4 ) along the flow direction ( 2 ) changed. Solid electrolyte fuel cell according to claim 1, characterized in that the electrochemical activity of the functional layer changes continuously over the flow direction and in particular that the electrochemical activity of the functional layer changes linearly or non-linearly over the flow direction. Solid electrolyte fuel cell according to claim 1, characterized in that the electrochemical activity of the functional layer via the flow direction linear, non-linear or stepped changes. Solid electrolyte fuel cell according to one of the preceding claims, characterized in that the electrochemical activity changes over the flow direction in accordance with a parabolic function or hyperbolic function. Solid electrolyte fuel cell according to one of the preceding claims, characterized in that at least one of the functional layers also has a degree of electrochemical activity across the thickness. Solid electrolyte fuel cell according to claim 5, characterized in that the gradation over the thickness of the functional layer is continuous or linear or graded or non-linear or designed according to a parabola function or hyperbola function. Solid electrolyte fuel cell according to one of the preceding claims, characterized in that the electrochemical activity of the gas inlet ( 3 ) to the gas outlet ( 4 ) increases according to the depletion of reacting gas to reactants. Solid electrolyte fuel cell according to one of the preceding claims, characterized in that the functional layer is formed of zirconium oxide, wherein the zirconium oxide is doped with doping elements, wherein the grading of the electrochemical activity, the type and amount of the doping elements contained is changed. A process for producing a solid electrolyte fuel cell having a serving as an anode and a cathode functional layer, which are separated by a Separatorschicht, wherein the functional layers are electrochemically active and a gas inlet and a gas outlet are present, wherein the gases to be converted from the gas inlet to the gas outlet Overflow respective functional layer along a flow direction, in particular for producing a solid electrolyte fuel cell according to one or more of claims 1 to 8, characterized in that at least one of the functional layers of a base material and at least one electrochemical activity affecting doping element are formed, wherein during application of the Functional layer the electrochemical activity of the operational functional layer via a gas flow direction ( 2 ) is changed in that a concentration gradient of the at least one doping element via the flow direction ( 2 ) is generated, so that during the application of an enrichment or depletion of the at least one doping element is made. A method according to claim 9, characterized in that during the deposition of a doping element depleted and at least one further enriched at the expense of the depleted doping element. A method according to claim 9 and / or 10, characterized in that for the enrichment and depletion of the respective doping element, the mixing ratio of at least two components is changed at the same order volume, wherein a first component of the mixture contains the base material and at least a first doping element and a second component the mixture contains the base material and at least one second doping element. Method according to one or more of claims 9 to 11, characterized in that the functional layer is produced by plasma spraying, thin-film or foil casting. A method according to claim 12, characterized in that for the production of at least one functional layer during plasma spraying, at least two pulverulent components are supplied to a plasma spraying device and sprayed in accordance with the desired mixing ratio. A method according to claim 13, characterized in that the powdered components of the mixture fed to a plasma torch, melted in an ionized gas stream, accelerated and applied to a substrate. A method according to claim 14, characterized in that the plasma torch is guided in a meandering manner over the substrate, similar to a paint spray gun. Method according to one or more of claims 13 to 15, characterized in that first the anode, then the separator and finally the cathode are sprayed. Method according to one or more of Claims 14 to 16, characterized in that a powder feed device with at least two separate powder feed systems for powders, each with different electrochemically active components, is connected to the plasma torch, wherein during the process of the plasma torch a control device controls the powder feed device and in particular the powder feed systems in such a way that the composition of the sprayed powder within the individual solid electrolyte fuel cell layers is targeted via the subsequent flow direction (FIG. 2 ) of a fuel gas is changed. Method according to one or more of claims 14 to 17, characterized in that the plasma torch is moved so that the meander ( 7 ) perpendicular to the fuel gas flow direction ( 2 ), wherein the composition of the mixture during a movement of the burner transversely to the later fuel gas flow direction ( 2 ) held constant over the substrate and in the process of the plasma torch with or against the flow direction ( 2 ) the powder delivery systems are controlled to increase the amount of one component at the expense of the amount of the other component or vice versa. Method according to one of claims 14 to 17, characterized in that the burner parallel with or against the later flow direction ( 2 ) is moved across the substrate, wherein in the promotion of the aufzuspritzenden powder, the amount of one component during the movement of the burner over the substrate continuously or stepped increased or decreased at the expense of the other component. A method according to claim 19, characterized in that, after the burner has passed over the substrate, a lateral displacement movement of the burner is performed and against the first direction of movement carried out a return movement is driven, in which the first sprayed process runs backwards, wherein the component was depleted during the first injection process, now enriched during the injection movement in the opposite direction again accordingly. A method according to claim 19, characterized in that the burner is moved with simultaneous spraying only in one direction, either in the flow direction or against the flow direction, wherein the control is performed so that the one component is initially added less and the dosing or proportion the component increases continuously or in steps during the overrunning of the substrate, while the proportion of the other component drops correspondingly, the plasma torch, after passing over the substrate, performing a return movement, wherein at the same time the metering is controlled so that after completion of the return movement again with a high Concentration of the first component is started and in the return movement, a splash does not take place. Method according to one or more of claims 10 to 21, characterized in that in addition a grading of the electrochemical activity in the thickness direction of the layers is carried out, so that after the substrate has once been completely covered with a layer, a next thin layer of the same function, for example an anode function, in which the starting composition is changed to the starting composition of the underlying layer with respect to the electrochemical activity. A method according to claim 22, characterized in that one of the components is enriched or depleted at the expense of the other or a third component is supplied. Use of a fuel cell according to one or more of claims 1 to 8 and in particular of a fuel cell produced by a process according to one or more of claims 9 to 23 as electrolyzer.

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