WO2009059443A1

WO2009059443A1 - Bipolar cell for fuel cell stack

Info

Publication number: WO2009059443A1
Application number: PCT/CH2008/000464
Authority: WO
Inventors: Ulf Bossel; Beat Gut
Original assignee: Almus Ag
Priority date: 2007-11-07
Filing date: 2008-11-05
Publication date: 2009-05-14

Abstract

The invention relates to the integration of all functions of a flat electrochemical cell into a bipolar cell. A bipolar cell comprises a bipolar plate (1) provided with gas channels (7, 8), at least one porous carrier layer (2), and at least one multi-layer film comprising the functional layers of electrode (3), electrolyte (4), and counter-electrode (5). The metal bipolar plate (1) is connected to the thin, gas-permeable carrier layer (2) in a heat-proof manner using suitable methods. The functional layers (3, 4 and 5) are applied onto the carrier layer (2) in accordance with the functions thereof using coating technology methods. The bipolar cell is cut out of the top multi-layer film using a suitable cutting method. Furthermore, one or more bores for conducting the reaction gases are cut out along the stack (9). From the wall of such a bore, connecting channels (10) are introduced into the bipolar plate to the corresponding gas channels (7 or 8) for the cathodic or anodic reaction gas.

Description

Bipolzelle for fuel cell stack

State of the art

For plate-shaped cells, a fuel cell stack consists of at least two repeat units, each having at least two separately manufactured components, namely an electrochemically active cell and a bipolar plate, which conducts both the current from one cell to the next, as well as for supplying the cell with fuel and air is. The parts are stacked on top of each other so that there is an electrical series circuit and two separate fuel and air gas supply systems in the stack. In the terminology of the electrodes, air is conventionally used as a cathodic reaction gas and fuel as an anodic reaction gas.

Level oxide ceramic cells are produced individually mainly by ceramic processing technology. Using the electrolyte as a supporting layer, the anode and cathode must be applied to the front and back of this, avoiding a short circuit between the electrodes by leaving the edges free. In anode-supported cells, a porous layer of anode material serves as a supporting substrate. An additional layer of anode material with a better microstructure for the electrochemical reactions is applied to this substrate. Then the same side is covered with a thin electrolyte layer and finally with a cathode layer. Again, the edge is released. For the optimization of the cell function, additional intermediate layers can be introduced. From the cathode is not known that it is used in flat cells as a supporting layer. As a supporting layer for even cells, porous metal sheets are also used, after which the functional layers are applied by suitable methods. Usual is the layer structure anode-electrolyte cathode, the reverse order is not excluded. It is important here that ceramic processing technology is completely dispensed with in cell production. However, in the case of individual production of the cells, the cell surface must be masked at least for the application of the second electrode, ie a portion of the electrolyte must be covered.

For bipolar stacking, oxide ceramic cells are placed in the correct sequence between bipolar plates with the appropriate gas guide. In this case, the gas spaces of the electrodes against each other and the anode space against the environment must be completed so far that no unwanted, direct combustion takes place. For stacking a variety of solutions are known. The behavior of the stack is essentially determined by the geometry of the gas guides. If air and fuel are passed through the cell in parallel, this is referred to as co-flow; if they are directed parallel to each other, this is counter-flow and if the gas flows cross, this is referred to as cross-flow. Each of these designs has its specific problem with the sealing of the electrode spaces and the thermal behavior of the stack. Examples include the sealing by means of a glass-ceramic paste or the welding of the cells into box-shaped metallic modules. The seal of the gas spaces between bipolar plate and cell can be most easily realized with cells carried by the electrolyte, because the two porous electrodes are thin and thus the leakage along the flat sealing zone to the edge is very low. Those of porous substrates Carrying cell types cause greater sealing problems, because the thicker porous substrate allows much higher leakage rates. The leakage can be reduced by infiltration of sealing media into the edge area of the substrates or by closing the edge. Both means additional effort in cell production.

The integration of the cells in the stack is crucial for the function of the fuel cell. The sealing of the gas chambers is not a trivial problem with even cells. The entire surface electrical contacting of an electrode with the adjacent bipolar plate must be ensured. The cells are pressed in the stack to the adjacent bipolar plates. In order to reduce the contact resistance between the bipolar plate and the electrodes, a contact paste of material which conducts electricity well and is similar to the respective electrode is often applied.

The ceramic cells described above are all relatively fragile. On the one hand, the cells should be as large as possible for optimal fuel utilization, on the other hand, the electrolyte must be thin in order to minimize the internal resistance of the cell. The latter can hardly be realized with cells carried by the electrolyte. At the anode carried cells, the electrolyte can be applied very thin. However, the porous substrate of these cells has poor mechanical properties and therefore needs to be made thicker. This leads to the already described sealing problems. All ceramic cells are very susceptible to breakage. They must therefore be handled with extreme care and tend to crack during operation. For procedural reasons, the ceramic cells are produced individually, so go through each of the necessary coating and sintering steps. Experience

By combining bipolar plates and cell into one component, some of the mentioned disadvantages of the described cells are overcome with this invention. The innovative Bipolzelle is a layer composite, which is mechanically supported by the bipolar plate (1). The open gas channels of the bipolar plate (1) are covered with a porous, thin carrier layer (2), wherein the carrier layer (2) is positively and electrically connected to the bipolar plate (1). The cell applied according to the invention by layer-forming methods (the functional layers (3, 4, 5) of ceramic material) thus needs no mechanical inherent stability and can be applied as thinly as the function of the layers permits. Since the bipolar plate (1) already contains the gas distribution systems (7, 8) for the reaction gases, no further component for the stack construction is necessary. This represents a stack repeat unit according to the invention and it is cut to size only after the planar application of the functional layers. When applying the functional layers no masking is necessary. The layer composite can thus be regarded as a semi-finished product that is manufactured by the meter and can be processed into batch repeat units. The coating area is not limited by the cell size.

The construction of a Bipolzelle allows bilateral coating of the bipolar plate with the functional layers, which largely eliminates the rejection of the composite layer as a result of different thermal expansion coefficients of the different materials. For coating on both sides, both sides of the supporting bipolar plate (1) are covered with a carrier layer (2). The functional layers are on the cathode side in the order of cathode, electrolyte, anode and anode side in the order of anode, electrolyte, cathode applied. As with batch repeat units, the last step in the process is cutting out of the layer composite. For stacking with such bipolar cells, an uncoated bipolar plate is placed between two cells.

For a rational mass production, the invention brings significant advantages. Compared to conventional methods, the manufacturing process runs in reverse order. Usually, substrates are first manufactured in cell size and then individually coated in several, because of the necessary masking labor intensive steps. In the method according to the invention, a flat coating without masking is provided. The batch repeating units or the bipolar cells are cut out of the layer composite in the last method step.

manufacturing steps

For the production of the inventive stack repeat units, the order of the production steps is changed so that a cost-effective mass production of high-quality cells is possible. The successive production steps A to H serve to explain the manufacturing process.

A. The preparation of batch repeat units begins with the incorporation of the channel structures (7, 8) for one or a plurality of bipolar plates into a sheet. This bipolar plate sheet may be tailored for one or more single cells. For continuous mass production can be used by the coil unwound metal strips. The Channel patterns may be incorporated into the bipolar plate sheet by stamping, forging, etching, milling, electroerosion or other methods. They are arranged with the necessary precision on the sheet so that in this state complete bipolar plates or after the steps B to F batch repeating units or bipolar cells can be cut out.

B. The carrier layer (2) is frictionally and electrically conductively connected to the Bipolaplatten- sheet over the entire surface or partially on each channel pattern (6). As a Tägerschicht a thin (0.1 to 0.5 mm thick) porous metal foil, a metal mesh or a metal foam can be used. The connection can be made by brazing, diffusion bonding, induction welding or other suitable method. The assignment of the bipolar plate sheet can be unilaterally either on the side of the fuel gas channels or on the side of the air ducts.

C. The first electrode layer (3) is applied to this carrier layer (2) over the whole area by means of a suitable method, the cathode in the air-side or the anode in the case of the fuel-side carrier layer. The layer can be made by thermal spraying, sputtering, or other layer-building techniques.

D. The electrolyte (4) is then applied over the entire surface. For the application, the same method as for application of the first electrode or another method can be used.

E. The corresponding counter electrode (5) is also applied over the entire surface. Again, the same or another coating method find application.

F. Depending on requirements, before or after steps C, D and E further intermediate layers can be applied, which serve as a catalyst for electrochemical reactions, for phase stabilization or as a diffusion barrier.

G. The batch repeat unit is now ready to be cut. This can be done by laser, water jet cutting, punching or other suitable processing methods. For this, each stack repeat unit or bipolar cells has to be cut out of the layer composite according to the prefabricated channel pattern.

H. After a quality control, the batch repeating units or the bipolar cells are ready for stacking.

For symmetrical biplates, steps A, F, G and H remain identical. In step B, a carrier layer (2) is applied on both sides, wherein the structure of the carrier layer can be different and adapted to the requirements of the cathode or the anode. Steps C to E may be alternately executed in this order for one page, or for one or two layers, respectively.

Description of the figures

1 layer structure of a planar Bipolzelle or a Stapelwiederholungseinheit and bore (9) in the stacking direction with connecting channel (10) to a gas distribution channel system in the bipolar plate. Fig. 2 layer structure of a planar Bipolzelle with coating on both sides and holes (9) in the stacking direction with connecting channels (10) to both gas distribution channel systems in the bipolar plate.

LIST OF REFERENCE NUMBERS

1 bipolar plate

2 Porous carrier layer

3 electrode (anode or cathode)

4 electrolyte

5 counter electrode (anode or cathode)

6 Metallic connection of bipolar plate and porous carrier layer

Gas duct system below (cathodic or anodic or air or fuel gas)

Gas duct system above (anodic or cathodic or fuel gas or air)

9 Bore through the planar Bipolzelle 0 Connecting channel from the bore to the flow channel

Claims

claims

1. Planar Bipolzelle for bipolar Brennstoffzellensta- pel characterized in that the functional electrochemical layers electrode, electrolyte and counter electrode at least on one side of the bipolar plate (1) as a layer composite (3, 4, 5) are applied to a porous pad (2), wherein the porous pad (2) is connected in a force-locking and electrically conductive manner to the stack-specific bipolar plate (1).

2. Planar Bipolzelle according to claim 1, characterized in that the stack-specific bipolar plate channels (7, 8) for the distribution of the reaction gases in the reaction chambers of the cell and for discharging the residual gases from the reaction chambers of the cell.

3. Planar Bipolzelle according to claim 1 and 2, characterized in that it has at least one bore (9) for the supply of the cathodic or anodic reaction gas along the stack and that from this bore connecting channels (10) to the channels for the distribution of cathodic or the anodic reaction gas go out.

4. Planar Bipolzelle according to claim 1, 2 and 3, characterized in that it comprises at least one further bore (9) and that lead to such a further bore (9) connecting channels (10) for the collection of either anodic or cathodic residual gas.

5. Planar Bipolzelle according to claim 1, characterized in that the porous pad (2) is a metal mesh, a porous metal foil, a finely perforated metal sheet or another porous structure.

6. Planar Bipolzelle according to claim 1, characterized in that the porous base (2) with the bipolar plate (1) on the air side or fuel side tig is connected and the layer composite at air side applied pad in the order of cathode (3), electrolyte (4) and anode (5) or fuel-applied base in the order of anode (3), electrolyte (4) and cathode (5) is applied.

7. Planar Bipolzelle according to claim 1 and 6, characterized in that on both sides of the bipolar plate, a corresponding layer composite is applied.

8. Planar Bipolzelle according to claim 1, 6 and 7, characterized in that the materials of the functional layers are adapted to the electrolyte, wherein as a classic example yttria stabilized zirconia as the electrolyte, Ni cermet as the anode and lanthanum-strontium manganate as the cathode applies. For later discovered as electrolyte material such as doped ceria or lanthanum galate electrode materials are adjusted accordingly.

9. Planar Bipolzelle according to claim 1, 6, 7 and 8, characterized in that lie between, or under or on the functional layers further layers, which serve the catalytic reaction acceleration, the electrical contact, the phase stabilization or as a diffusion barrier.