The present invention relates to an improvement of fuel cells such as polymer electrolyte fuel cells, in particular to a fuel cell stack in which a plurality of single cells each including a membrane electrode assembly and a pair of separators is stacked.
For example, one of such fuel cell stacks in the art is described in Patent Document 1. The fuel cell stack described in Patent Document 1 includes electrolyte-electrode assemblies and metal separators that are alternately stacked in the horizontal direction, in which fluid communication holes for distributing coolant or reaction gas penetrate in the stacking direction. Further, the fuel cell stack is configured such that insulative members are provided to the metal separators to cover the surfaces of the metal separators and the inner walls of the fluid communication holes so that the sealing property against the coolant or the reaction gas is secured by means of the insulative members.
In fuel cell stacks as describe above, water is generated along with power generation, and a fluid discharging communication hole is used also as a route for discharging the generated water among the fluid communication holes formed in the stacking direction. However, a problem with the conventional fuel cell stack is that the generated water is likely to be retained inside the fluid communication hole since the fluid communication holes have uneven inner walls due to the gaps between the layers, and it has been required to solve the problem.
For example, a possible measure for preventing such retention of the generated water in the fluid communication hole is to cover the entire inner wall of the fluid communication hole with an insulative member. However, this results in the high production cost. Further, the flow area is changed depending on the temperature and the compression condition of the insulative member, which may have a negative influence on the pressure loss of the channel and the distribution of fluid to each single cell.
The present invention has been made in view of the above-described problem with the prior art, and an object thereof is to provide a fuel cell stack that includes a manifold for distributing reaction gas in the stacking direction and that can suitably discharge generated water through the manifold without a decrease of the flowability of the reaction gas and an increase of the production cost.
The fuel cell stack according to the present invention includes a stacked plurality of single cells, each of the single cells having a membrane electrode assembly with a peripheral frame and a pair of separators that hold the peripheral frame and the membrane electrode assembly between them. Further, the fuel cell stack is configured such that the peripheral frames and separators of the single cells have respective distribution holes that continue to each other in the stacked state to form a manifold for distributing reaction gas, and at least a part of the inner wall of the manifold is formed in a continuous flat shape that extends in the stacking direction of the plurality of single cells.
The fuel cell stack according to the present invention includes the manifold for the reaction gas in the stacking direction, in which at least a part of the inner wall of the manifold is formed in a gapless continuous flat shape extending in the stacking direction of the single cells by the end faces (the inner walls of the distribution holes) of the stacked members such as the frames and the separators without any special member. That is, the end faces of the stacked members continue to be flush with each other at least in a part of the inner wall of the manifold.
With this configuration, the fuel cell stack can suitably discharge generated water through the manifold without a decrease of the flowability of the reaction gas and an increase of the production cost. Further, since the fuel cell stack exhibits good water drainage, corrosion of the stacked members such as the frames and the separators due to the retained generated water can be prevented even when the end faces of the stacked members are exposed in the inner wall of the manifold.
The fuel cell stack FS in
In the fuel cell stack FS, the fastening plates 57A, 57B and the reinforcing plates 58A, 58B are each coupled to both of the end plates 56B, 56B with bolts B. As described above, the fuel cell stack FS has a case-integrated structure as illustrated in
As illustrated in
The membrane electrode assembly 1, which is generally referred to as an MEA, has a structure known in the art in which an electrolyte layer of a solid polymer is intervened between an anode electrode layer and a cathode electrode layer although the detailed structure is not shown in the figure.
The frame 51 is integrally formed with the membrane electrode assembly 1 by resin molding (e.g. injection molding). In the embodiment, the frame 51 has a rectangular shape, and the membrane electrode assembly 1 is disposed at the center thereof. Further, the frame 51 has distribution holes H1 to H3, H4 to H6 for distributing reaction gas, which are disposed such that three holes are arranged at both short sides.
The separators 2A, 2B are constituted by rectangular metal plate members having approximately the same length and width as the frame 5. For example, the separators 2A, 2B are made of stainless steel, and one plate has inverted faces to those of the other plate. In the illustrated example, the separators 2A, 2B have an uneven cross section at least at the center part opposed to the membrane electrode assembly 1. The uneven shape of the separators 2A, 2B continuously extends in the longitudinal direction. The tips of the corrugation are in contact with the membrane electrode assembly 1 while the recesses of the corrugation form the anode and cathode gas channels between the separators 2A, 2B and the membrane electrode assembly 1. Further, the separators 2A, 2B have distribution holes H1 to H6 at the short sides that are formed in the similar manner as the distribution holes H1 to H6 of the frame 51.
The above-described membrane electrode assembly 1 with the frame 51 and the separators 2A, 2B are laminated to each other to form a single cell C. In the single cell C, the distribution holes H1 to H6 of the frame 51 and the separators 2A, 2B are connected to corresponding holes to respectively form manifold M1 to M6 for distributing reaction gas. Further, a plurality of single cells C are stacked to constitute the fuel cell stack (stack A) FS, and a channel for cooling fluid is formed between single cells C adjacent in the stacking direction. In this way, the fuel cell stack FS has the manifolds M1 to M6 for distributing reaction gas in the stacking direction of the single cells C.
In the single cell C in
As illustrated in the frame 51 and the membrane electrode assembly 1 of
At the anode side as illustrated in
At the cathode side as illustrated in
In the fuel cell stack FS including a stacked plurality of single cells C, at least a part of the inner wails of the manifolds M3, M6 for discharging reaction gas is formed in a continuous flat shape that extends in the stacking direction of the plurality of single cells C. To be more specific, in the fuel cell stack FS, the end faces (inner walls of the distribution holes H3, H6) of the stacked members, which are the frames 51 and the separators 2A, 2B, form the inner walls of the manifolds M3, M6 which are at least partly formed in a continuous flat shape that extends in the stacking direction of the plurality of single cells C. That is, the end faces of the stacked members (51, 2A, 2B) continue to be flush with each other at least in a part of the inner walls of the manifolds M3, M6.
The fuel cell stack FS of the embodiment is installed such that the long sides of the single cells C are horizontal as illustrated in
In the embodiment, as illustrated in the enlarged cross section of
To be more specific, the frames 51 include integrally formed respective ribs 21 that protrude from the cathode side (lower side in
The above-described gas sealings S are provided between the edges of the respective distribution holes H3 of the anode separators 2A and the frames 51, between the edges of the respective distribution holes H3 of the frames 51 and the cathode separators 2B and between the edges of the cathode separators 2B and the anode separators 2A of adjacent single cells C.
Since the illustrated example of the fuel cell stack FS includes the ribs 21 that protrude from the cathode side of the frames 51, the gas sealings are provided between the top faces of the ribs 21 and the cathode separators 2B. The above-described openings for distributing the cathode gas can be formed by partly removing the ribs 21. While
In the fuel cell stack FS with the above-described configuration, each of the single cells C generates electric power by electrochemical reaction when the anode gas and the cathode gas are supplied respectively to the anode electrode layer and the cathode electrode layer of the membrane electrode assembly 1. Along with the power generation, water is generated. The generated water is discharged mainly through the manifolds M3, M6 for discharging the reaction gas.
In this regard, in the fuel cell stack FS, the end faces of the stacked members, which are the frames 51 and the separators 2A, 2B, form the inner wall of the manifold M3, at least a part of which is formed in a continuous flat shape that extends in the stacking direction of the single cells C without any gaps.
Particularly in the fuel stack FS of the embodiment, the frames 51 and the separators 2A, 2B respectively have the flattening faces F1 to F3 in the inner walls of the distribution holes H3, and the flattening faces F1 to F3 continues to each other to be flash in the same flat face so that at least a part of the inner wall of the manifold M3 is formed in a continuous flat shape that extends in the stacking direction of the single cells C.
With this configuration, the fuel cell stack FS can suitably discharge the generated water through the manifold M3 without a decrease of the flowability of the reaction gas and an increase of the production cost. Further, in the fuel cell stack FS, the good drainage can prevent corrosion of the stacked members (51, 2A, 2B) due to the retained generated water even though the end faces (i.e. the flattening faces F1 to F3) of the stacked members, which are frames 51 and the separators 2A, 2B, are exposed in the inner wall of the manifold M3.
In the fuel cell stack FS of the embodiment, the generated water can be smoothly and rapidly discharged since the part formed in a flat shape in the inner wall of the manifold M3 is at least in the lower side of the inner wall of the manifold M3 with respect to the direction of gravity.
In the fuel cell stack FS in
In the fuel cell stack FS, the flattening faces F1 of the frames 51 continue to be flush with each other so that at least a part of the inner wall of the manifold M3 is formed in a gapless continuous flat shape that extends in the stacking direction of the single cells C. That is, while the flattening faces F1 to F3 of the frames 51 and the separators 2A, 2B form the flat face of the manifold M3 in the previously-described first embodiment, only the flattening faces F1 of the frames 51 form the flat face of the manifold M3 in this embodiment.
As with the first embodiment, this fuel cell stack FS can suitably discharge generated water through the manifold M3 without a decrease of the flowability of reaction gas and an increase of the production cost. Further, since the ribs 21 of the resin frames 51 cover the inner walls of the distribution holes H3 of the metal separators 2A, 2B, generated water does not come in contact with these inner walls. This can impart a function of sufficiently protecting the inner walls against corrosion to the fuel cell stack FS,
A frame 51 of the single cell C of
The single cell C includes adhesive portions in the edge of the distribution hole H3 of the frame 51 for adhesion to the opposed members adjacent in the stacking direction and pits for adhesive 22 on the opposite side of the adhesive portions from the distribution hole.
The adhesive 22 is applied on the adhesive portions and serves as sealing after curing. The adhesive portions are equivalent of the above-described gas sealings (see
As with the previously-described embodiments, the fuel cell stack, in which a plurality of fuel cells C with the above-described configuration is stacked, can suitably discharge generated water through the manifold M3 without a decrease of the flowability of reaction gas and an increase of the production cost. Furthermore, the gaps between the frames 51 and the separators 2A, 2B are completely filled with the adhesive 22, and the pits 23 can release excess adhesive 22 to prevent it from being extruded to the distribution holes H3. Therefore, the inner wall of the manifold M3 can be formed in a flat shape.
A frame 51 of the single cell C of
The single cell C includes adhesive portions in the edge of the distribution hole H3 of the frame 51 for adhesion to the opposed members (separators 2A, 2B) adjacent in the stacking direction and pits 23 for adhesive 22 on the opposite side of the adhesive portions 22 from the distribution hole H3. Further, the adhesive portions have inclined faces 24 that form downward slopes to the pits 23.
As with the previously-described embodiments, the fuel cell stack, in which a plurality of single cells C with the above-described configuration is stacked, can suitably discharge generated water through the manifold M3 without a decrease of the flowability of reaction gas and an increase of the production cost. Furthermore, the gaps between the frames 51 and the separators 2A, 2B are completely filled with the adhesive 22, and the inclined faces 24 can actively release excess adhesive 22 to the pits 23. This can prevent extrusion of the adhesive 22 to the distribution holes H3 more reliably, and the inner wall of the manifold M3 can therefore be formed in a flat shape.
The configuration of the fuel cell stack of the present invention is not limited to the above-described embodiments. The details of the configuration can be suitably changed, or the configurations of the above-described embodiments can be suitable combined without departing from the features of the present invention.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/063753 | 5/13/2015 | WO | 00 |