Disclosed herein is a novel fuel cell stack assembly. In one embodiment, the stacks of the present invention comprise: a first and a second end plate; a plurality of fuel cells interposed between the first and second end plates, at least one of the fuel cells having a unitized MEA assembly and/or a
Disclosed herein is a novel fuel cell stack assembly. In one embodiment, the stacks of the present invention comprise: a first and a second end plate; a plurality of fuel cells interposed between the first and second end plates, at least one of the fuel cells having a unitized MEA assembly and/or a compound flow field; a means to separate neighboring fuel cell components; and a compression means.
대표청구항▼
What is claimed is: 1. A fuel cell stack comprising: (a) a first end plate and a second end plate, the second end plate being aligned with the first end plate; (b) a plurality of fuel cells interposed between the first and second end plates, at least one of the fuel cells comprising: (i) a cantilev
What is claimed is: 1. A fuel cell stack comprising: (a) a first end plate and a second end plate, the second end plate being aligned with the first end plate; (b) a plurality of fuel cells interposed between the first and second end plates, at least one of the fuel cells comprising: (i) a cantilevered unitized MEA assembly, the cantilevered unitized MEA assembly comprising an MEA and a frame, the MEA being sealed within the frame, (ii) an anode flow field, (iii) a cathode flow field, and (iv) wherein the anode flow field comprises a primary flow field and a mating flow field, wherein the primary flow field includes a plurality of valleys and the mating flow field includes a plurality of recessed areas corresponding to respective ones of the valleys to form a plurality of microchannels; (c) a plurality of internal foils, each internal foil having an first connection surface and a second connection surface; and (d) a compression means, the compression means securing the end plates, the plurality of fuel cells, and the plurality of internal foils to form the fuel cell stack. 2. The fuel cell stack according to claim 1 wherein the first connection surface of a first internal foil is juxtaposed to the anode flow field of a first fuel cell, and the second connection surface of the first internal foil is juxtaposed to the cathode flow field of a second fuel cell. 3. The fuel cell stack according to claim 1 wherein the first connection surface of a first internal foil is juxtaposed to the anode flow field of a first fuel cell and the second connection surface of the first internal foil is juxtaposed to a heat exchange means, and wherein the first connection surface of a second internal foil is juxtaposed to the heat exchange means and the second connection surface of the second internal foil is juxtaposed to the cathode flow field of a second fuel cell. 4. The fuel cell stack according to claim 1 wherein the cathode flow field comprises a primary flow field and a mating flow field. 5. The fuel cell stack according to claim 1 wherein the anode flow field or the cathode flow field comprises a reticulated structure. 6. The fuel cell stack according to claim 1 wherein the anode flow field or the cathode flow field have a plurality of corrugations. 7. The fuel cell stack according to claim 6 wherein a first subset of corrugations are substantially located in a first plane, a second subset of corrugations are substantially located in a second plane, the first plane is substantially parallel to the second plane, and neighboring corrugations belong to different subsets. 8. The fuel cell stack according to claim 1 wherein the first end plate and the second end plate are constructed primarily from a plastic material. 9. The fuel cell stack according to claim 1 wherein the first end plate or the second end plate are substantially circular, substantially rectangular, or substantially square. 10. The fuel cell stack according to claim 1 wherein the compression means comprises a threaded fastener. 11. The fuel cell stack according to claim 1 wherein the cantilevered unitized MEA assembly further comprises a sealing clamp. 12. The fuel cell stack according to claim 1 wherein the frame of the unitized MEA comprises orifices for use in conjunction with the compression means. 13. The fuel cell stack according to claim 1 wherein the frame of the unitized MEA further comprises apertures substantially identical to apertures of the first end plate or second end plate for use in conjunction with the compression means. 14. A fuel cell stack comprising: (a) a first end plate and a second end plate, the second end plate being aligned with the first end plate; (b) a plurality of fuel cells, the fuel cells being interposed between the first end plate and the second end plate, and at least one of the fuel cells comprising: (i) at least one compound flow field including a primary flow field having a plurality of corrugations and a mating flow field including a plurality of recessed areas, (ii) a second flow field, (iii) an MEA, and (iv) a frame; (c) a plurality of internal foils, each internal foil having an first connection surface and a second connection surface; and (d) a compression means, the compression means securing the end plates, the plurality of fuel cells, and the plurality of the internal foils together. 15. The fuel cell stack according to claim 14 wherein the compound flow field comprises the an anode flow field of the fuel cell. 16. The fuel cell stack according to claim 14 wherein the compound flow field comprises a cathode flow field of the fuel cell. 17. The fuel cell stack according to claim 14 wherein the second flow field is a compound flow field. 18. The fuel cell stack according to claim 14 wherein the frame and the MEA form a unitized MEA assembly. 19. The fuel cell stack according to claim 15 wherein the first connection surface of a first internal foil is juxtaposed to the compound anode flow field of a first fuel cell, and the second connection surface of the first internal foil is juxtaposed to the second flow field of a second fuel cell. 20. The fuel cell stack according to claim 14 wherein the first connection surface of a first internal foil is juxtaposed to the compound flow field of a first fuel cell and the second connection surface of the first internal foil is juxtaposed to a heat exchange means, and wherein the first connection surface of a second internal foil is juxtaposed to the heat exchange means and the second connection surface of the second internal foil is juxtaposed to the second flow field of a second fuel cell. 21. The fuel cell stack according to claim 14 wherein the first connection surface of a first internal foil is juxtaposed to the second flow field of a first fuel cell and the second connection surface of the first internal foil is juxtaposed to a heat exchange means, and wherein the first connection surface of a second internal foil is juxtaposed to the heat exchange means and the second connection surface of the second internal foil is juxtaposed to the compound flow field of a second fuel cell. 22. The fuel cell stack according to claim 14 wherein the first end plate or the second end plate are constructed primarily from a plastic material. 23. The fuel cell stack according to claim 14 wherein the first end plate or the second end plate are substantially circular, substantially rectangular, or substantially square. 24. The fuel cell stack according to claim 14 wherein the compression means comprises threaded fastener. 25. A fuel cell stack comprising: (a) a first end plate and a second end plate, the second end plate being aligned with the first end plate; (b) a plurality of fuel cells, the fuel cells being interposed between the first end plate and the second end plate, and at least one of the fuel cells comprising: (i) a first compound flow field, (ii) a second compound flow field, (iii) a unitized MEA assembly, the unitized MEA assembly comprising an MEA and a frame, the MEA being sealed within the frame; and (iv) wherein each of the first and second compound flow fields include primary and mating flow fields, the primary flow field being corrugated and having a plurality of valleys, the mating flow fields including a plurality of recessed areas corresponding to respective ones of the valleys to form a plurality of microchannels, the mating flow fields further including at least one positioning peak operable to position the primary flow field with respect to the mating flow field; (c) a plurality of internal foils, each internal foil having an first connection surface and a second connection surface; and (d) a compression means, the compression means securing the end plates, the plurality of fuel cells, and the plurality of internal foils together. 26. The fuel cell stack according to claim 25 wherein the first compound flow field is an anode flow field of the fuel cell, and the second compound flow field is a cathode flow field of the fuel cell. 27. The fuel cell stack according to claim 26 wherein the first connection surface of a first internal foil is juxtaposed to the compound anode flow field of a first fuel cell, and the second connection surface of the first internal foil is juxtaposed to the second compound flow field of a second fuel cell. 28. The fuel cell stack according to claim 25 wherein the first connection surface of a first internal foil is juxtaposed to the first compound flow field of a first fuel cell and the second connection surface of the first internal foil is juxtaposed to a heat exchange means, and wherein the first connection surface of a second internal foil is juxtaposed to the heat exchange means and the second connection surface of the second internal foil is juxtaposed to the second compound flow field of a second fuel cell. 29. The fuel cell stack according to claim 25 wherein the first connection surface of a first internal foil is juxtaposed to the second compound flow field of a first fuel cell and the second connection surface of the first internal foil is juxtaposed to a heat exchange means, and wherein the first connection surface of a second internal foil is juxtaposed to the heat exchange means and the second connection surface of the second internal foil is juxtaposed to the first compound flow field of a second fuel cell. 30. The fuel cell stack according to claim 25 wherein a first subset of corrugations are substantially located in a first plane, a second subset of corrugations are substantially located in a second plane, the first plane is substantially parallel to the second plane, and neighboring corrugations belong to different subsets. 31. The fuel cell stack according to claim 25 wherein the first end plate and the second end plate are constructed primarily from a plastic material. 32. The fuel cell stack according to claim 25 wherein the first end plate or the second end plate are substantially circular, substantially rectangular, or substantially square. 33. The fuel cell stack according to claim 25 wherein the compression means comprises a threaded fastener. 34. The fuel cell stack according to claim 25 wherein the unitized MEA assembly is a cantilevered unitized MEA assembly. 35. The fuel cell stack according to claim 34 wherein the cantilevered unitized MEA assembly further comprises a sealing clamp. 36. The fuel cell stack according to claim 25 wherein the unitized MEA assembly is a sandwich unitized MEA assembly.
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