초록

A plate, e.g. a bipolar plate, for fuel cells for (a) conducting current from the anode of one cell unit to the cathode of the adjacent cell unit and/or (b) distributing fluid which comprises a substrate with a coating of an electrocatalytically-active material comprising ruthenium oxide.

대표청구항 ▼

1. A fuel cell assembly including at least one plate for (a) conducting current and/or (b) distributing fluid, the plate comprising a metallic substrate with a coating of an electrocatalytically-active material comprising ruthenium oxide. 2. The fuel cell assembly of claim 1, wherein the plate is a

1. A fuel cell assembly including at least one plate for (a) conducting current and/or (b) distributing fluid, the plate comprising a metallic substrate with a coating of an electrocatalytically-active material comprising ruthenium oxide. 2. The fuel cell assembly of claim 1, wherein the plate is a terminal plate. 3. The fuel cell assembly of claim 1 in which the plate is an intermediate separator plate operable in use to conduct current from the anode of one fuel cell unit to the cathode of the adjacent fuel cell unit and/or distribute fluid flow in the fuel cell assembly. 4. The fuel cell assembly of claim 1, being a phosphoric acid fuel cell. 5. A PEM, phosphoric acid or direct methanol fuel cell assembly, for (a) conducting current and/or (B) distributing fluid, comprising at least one plate comprising a metallic substrate with a coating of an electrocatalytically-active material comprising a mixture of ruthenium or an oxide thereof, and a metal or oxide of a metal selected from the group comprising Sn, Fe, Co, Ni or Os. 6. A fuel cell assembly including at least one bipolar or separator plate for disposition between adjacent fuel cell units for (a) conducting current and/or (b) distributing fluid, said at least one plate comprising a metallic substrate with a coating of an electrocatalytically-active material comprising ruthenium oxide. 7. The fuel cell assembly of claim 6 in which the electrocatalytically-active material further comprises, in addition to ruthenium oxide, at least one other metal oxide. 8. The fuel cell assembly of claim 6 in which the electrocatalytically-active material further comprises, in addition to ruthenium oxide, at least one metal or metal oxide from Group 8 of the Periodic Table of Elements. 9. The fuel cell assembly of claim 6 in which the electroactively-active material further comprises, in addition to ruthenium oxide, at least one of PtO, Sb 2 O 3 , Ta 2 O 5 , PdO, CeO 2 , Co 3 O 4 , TiO 2 , SnO 2 and IrO 2 . 10. The fuel cell assembly of claim 6 in which the electroactively-active material further comprises, in addition to ruthenium oxide, TiO 2 . 11. The fuel cell assembly of claim 6 in which the electroactively-active material further comprises, in addition to ruthenium oxide, SnO 2 . 12. The fuel cell assembly of claim 6 in which the electroactively-active material further comprises, in addition to ruthenium oxide, IrO 2 . 13. The fuel cell assembly of claim 6, the plate having a fluid inlet aperture and a fluid outlet aperture and bring provided with surface features forming channels for conducting fluid flow from the inlet aperture to the outlet aperture. 14. The fuel cell assembly of claim 13 in which the inlet and outlet apertures are located at opposite sides of the plate and the surface features are located in the region of the plate extending between the inlet and outlet apertures. 15. The fuel cell assembly of claim 13 in which the surface features comprise a series of corrugations or a serpentine pattern. 16. The fuel cell assembly of claim 13, the surface features being embossed, etched, engraved, moulded, stamped, or die cast. 17. The fuel cell assembly of claim 13 in which the plate has a further fluid inlet aperture and a further fluid outlet aperture and is provided on its opposite face with surface features forming channels for conducting fluid flow from the further inlet aperture to the further outlet aperture. 18. The fuel cell assembly of claim 13 in which the inlet and outlet apertures are located at opposite sides of the plate. 19. The fuel cell assembly of claim 18 including surface features located in the region of the plate extending between the inlet and outlet apertures. 20. The fuel cell assembly of claim 6 in which the substrate is a metal selected from Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zr, Nb, Ag, Pt, Ta, Pb, Al or alloys thereof. 21. The fuel cell assembly of claim 6, the substrate of the plate being of aluminum or an alloy thereof. 22. The fuel c ell assembly of claim 6, the substrate of the plate being of titanium or an alloy thereof. 23. The fuel cell assembly of claim 6, the substrate of the plate being of iron or an alloy thereof. 24. The fuel cell assembly of claim 6 in which the substrate is of monolithic structure. 25. The fuel cell assembly of claim 6 in which the substrate is of composite structure. 26. The fuel cell assembly of claim 6 wherein said at least one plate includes fittings for connection to an external electrical circuit to which energy generated by the assembly is to be supplied. 27. The fuel cell assembly of claim 6 including pipework for conducting fluids to and/or from the assembly. 28. The fuel cell assembly of claim 27 in which the internal surfaces of the pipework are at least in part coated with said coating. 29. The fuel cell assembly of claim 6, being a PEM, phosphoric acid or direct methanol fuel cell. 30. The fuel cell assembly of claim 6 including separator plates and end and/or current-collecting plates, and is in which only the end and/or current-collecting plates of the assembly are provided with said coating. 31. The fuel cell assembly of claim 6 including separator plates and end and/or current-collecting plates, and is in which the end and/or current-carrying plates and only some of the separator plates are provided with said coating. 32. A plate, for use in a fuel cell assembly, for (a) conducting current and/or (b) distributing fluid, the plate comprising a substrate with a coating of an electrocatalytically-active material comprising a nickel/cobalt spinel, wherein said substrate comprises at least one metal selected from Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zr, Nb, Ag, Pt, Ta, Pb, Al or alloys thereof. 33. A fuel cell assembly comprising a plurality of individual fuel cell units each comprising an anode, a cathode and ion exchange membrane disposed between the anode and the cathode, a plurality of bipolar or separator plates located between the anode of one unit and the cathode of an adjacent unit, and end and/or current-collecting plates associated with the assembly, wherein at least one of the end and/or current-collecting plates and/or at least one of the bipolar or separator plates comprises a metallic substrate provided with a coating of an electrocatalytically-active material comprising ruthenium oxide or a mixture of ruthenium or oxide thereof, and a metal or oxide of a metal selected from Sn, Fe, Co, Ni or Os. 34. The fuel cell assembly of claim 33 including means for cooling the interior of the assembly. 35. The fuel cell assembly of claim 33 in which the end and/or current-collecting plates are provided with projections for engagement with a support surface to support the remainder of the assembly in spaced relation with the surface. 36. The fuel cell assembly of claim 33 in which the end and/or current-collecting plates comprise the primary means for the application of compression to the assembly. 37. The fuel cell assembly of claim 33 in which compression is applied to the end and/or current-collecting plates and to the remainder of the assembly by means of compression-applying plates located outboard of the end plates. 38. The fuel cell assembly of claim 33 in which the end and/or current-collecting plates are thicker than the separator plates. 39. The fuel cell assembly of claim 33 including humidifying means for introducing water vapour into the fuel and oxidant streams supplied to the assembly. 40. A fuel cell assembly as claimed in claim 33 in which said metallic substrate comprises a metal selected from the group comprising aluminum or an alloy thereof; titanium or an alloy thereof; iron or an alloy thereof; and stainless steel. 41. A fuel cell assembly comprising:a) a plurality of fuel cell units each of which contains a proton-exchange membrane separating the cell into anolyte and catholyte chambers and provided with an anode and a cathode on opposite sides thereof;b) a separator or bipolar plate disposed betwe en adjacent cell units;c) end and/or current-collecting plates associated with the assembly;d) means for feeding hydrogen fuel to the anolyte chambers of the assembly; ande) means for feeding an oxygen-containing gas to the catholyte chambers of the assembly;wherein at least one end and/or current-collecting plate and/or at least one separator plate or bipolar plate comprises a metallic substrate provided with a coating of an electrocatalytically-active material comprising ruthenium oxide or a mixture of ruthenium or oxide thereof, and a metal or oxide of a metal selected from Sn, Fe, Co, Ni or Os. 42. A plate, for use in a fuel cell assembly, for (a) conducting current and/or (b) distributing fluid, the plate comprising a stainless steel substrate with a coating of an electrocatalytically-active material that comprises ruthenium oxide and an oxide selected from the group comprising TiO 2 , SnO 2 and IrO 2 . 43. A plate, for use in a fuel cell assembly, (a) conducting current and/or (b) distributing fluid, the plate comprising a substrate with a coating of an electrocatalytically-active material comprising a nickel/cobalt spinel, the substrate comprising a metal selected from the group comprising Ti, Fe, Al, and alloys thereof. 44. A fuel cell assembly including at least one end plate and/or current-collecting plate for (a) conducting current and/or (b) distributing fluid, said at least one plate comprising a metallic substrate with a coating of an electrocatalytically-active material comprising ruthenium oxide. 45. The fuel cell assembly of claim 44 in which the electrocatalytically-active material further comprises, in addition to ruthenium oxide, at least one other metal oxide. 46. The fuel cell assembly of claim 44 in which the electrocatalytically-active material further comprises, in addition to ruthenium oxide, at least one metal or metal oxide from Group 8 of the Periodic Table of Elements. 47. The fuel cell assembly of claim 44 in which the electroactively-active material further comprises, in addition to ruthenium oxide, at least one of PtO, Sb 2 0 3 , Ta 2 0 5 , PdO, CeO 2 , Co 3 O 4 , TiO 2 , SnO 2 and IrO 2 . 48. The fuel cell assembly of claim 44 in which the electroactively-active material further comprises, in addition to ruthenium oxide, TiO 2 . 49. The fuel cell assembly of claim 44 in which the electroactively-active material further comprises, in addition to ruthenium oxide, SnO 2 . 50. The fuel cell assembly of claim 44 in which the electroactively-active material further comprises, in addition to ruthenium oxide, IrO 2 . 51. The fuel cell assembly of claim 44, the plate having a fluid inlet aperture and a fluid outlet aperture and bring provided with surface features forming channels for conducting fluid flow from the inlet aperture to the outlet aperture. 52. The fuel cell assembly of claim 44 in which the substrate is a metal selected from Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zr, Nb, Ag, Pt, Ta, Pb, Al or alloys thereof. 53. The fuel cell assembly of claim 44, the substrate of the plate being of aluminum or an alloy thereof. 54. The fuel cell assembly of claim 44, the substrate of the plate being of titanium or an alloy thereof. 55. The fuel cell assembly of claim 44, the substrate of the plate being of iron or an alloy thereof. 56. The fuel cell assembly of claim 44 in which the substrate is of monolithic structure. 57. The fuel cell assembly of claim 44 in which the substrate is of composite structure. 58. The fuel cell assembly of claim 44 wherein said at least one plate includes fittings for connection to an external electrical circuit to which energy generated by the assembly is to be supplied. 59. The fuel cell assembly of claim 44 including pipework for conducting fluids to and/or from the assembly. 60. The fuel cell assembly of claim 44, being a PEM, phosphoric acid or direct methanol fuel cell. 61. The fuel cell assembly of claim 44 including separator plates and end and/or curren t-collecting plates, and in which only the end and/or current-collecting plates of the assembly are provided with said coating. 62. The fuel cell assembly of claim 44 including separator plates and end and/or current-collecting plates, and in which the end and/or current-carrying plates and only some of the separator plates are provided with said coating.