Fuel cell stack having a plurality of liquid-cooled, bipolar plates separating one cell from the next. Coolant inlet and outlet manifolds are defined, in part, by surfaces of the bipolar plates, and respectively supply coolant to, and remove coolant from, the bipolar plates. The surfaces of the bipo
Fuel cell stack having a plurality of liquid-cooled, bipolar plates separating one cell from the next. Coolant inlet and outlet manifolds are defined, in part, by surfaces of the bipolar plates, and respectively supply coolant to, and remove coolant from, the bipolar plates. The surfaces of the bipolar plates that define the coolant manifolds and confront the coolant in the manifolds are coated with a non-conductive coating to reduce shunt current flow through the coolant.
대표청구항▼
1. In a PEM fuel cell comprising a plurality of cells arranged in a stack, each cell comprising an anode exposed to a first reactant, a cathode exposed to a second reactant and a membrane-electrolyte interjacent said anode and cathode, at least one electrically conductive, bipolar plate separating o
1. In a PEM fuel cell comprising a plurality of cells arranged in a stack, each cell comprising an anode exposed to a first reactant, a cathode exposed to a second reactant and a membrane-electrolyte interjacent said anode and cathode, at least one electrically conductive, bipolar plate separating one of said cells from the next, said bipolar plate comprising (a) an electrically conductive, active region having a first face confronting the anode of one cell in said stack, a second face confronting the cathode of the next adjacent cell in said stack, and an internal cooling passage for circulating coolant through said plate behind said faces, and (b) an electrically conductive inactive region bordering said active region, said inactive region having a surface defining an opening in said inactive region that in part defines a manifold adapted to supply coolant to said passage or remove coolant from said passage, the improvement comprising an adherent, non-conductive coating on said surface to reduce the flow of shunt currents through said coolant in said manifold. 2. A fuel cell according to claim 1 wherein said coating is selected from the group consisting of oxides and polymers. 3. A fuel cell according to claim 1 wherein said electrically conductive bipolar plate comprises a metal and said non-conductive coating comprises an oxide of said metal anodically grown in situ on said metal. 4. A fuel cell according to claim 3 wherein said metal is titanium and said inactive region comprises anodized titanium. 5. In a fuel cell comprising a plurality of cells arranged in a stack, each cell comprising an anode exposed to a first reactant, a cathode exposed to a second reactant and an electrolyte interjacent said anode and cathode, at least one electrically conductive, bipolar plate separating one of said cells from the next, said bipolar plate comprising (a) an electrically conductive, active region having a first face confronting the anode of one cell in said stack, a second face confronting the cathode of the next adjacent cell in said stack, and an internal cooling passage for circulating coolant through said plate behind said faces, and (b) an electrically conductive inactive region bordering said active region, said inactive region having a surface defining an opening in said inactive region that in part defines a manifold adapted to supply coolant to said passage or remove coolant from said passage, the improvement comprising an adherent, non-conductive coating on said surface to reduce the flow of shunt currents through said coolant in said manifold.
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이 특허에 인용된 특허 (5)
Balko Edward N. (Wilmington MA) Moulthrop Lawrence C. (Stratham NH), Apparatus for reduction of shunt current in bipolar electrochemical cell assemblies.
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