Fuel Cell Assembly and Method for Operating a Fuel Cell Assembly

1 .- 8 . (canceled) 9 . A fuel cell assembly with at least one proton exchange membrane fuel cell for generating electrical energy from reactant gases comprising hydrogen and oxygen, comprising: at least one membrane/electrode unit having a membrane coated with platinum electrodes and having, respectively positioned on each side thereof, a porous gas diffusion layer; bipolar plates which lie against each porous diffusion layer and through which, during operation, a coolant flows; wherein at least one platinum electrode has a smaller area than the gas diffusion layer; wherein the gas diffusion layer protrudes beyond the platinum electrode for a part of an edge region of the membrane/electrode unit and the gas diffusion layer does not protrude beyond the platinum electrode for another part of the edge region of the membrane/electrode unit; and wherein the edge region is a region around an outer periphery of the membrane/electrode unit. 10 . The fuel cell as claimed in claim 9 , wherein the protrusion of the gas diffusion layer beyond the platinum electrode is provided in one of (i) at a region of a coolant exit from the bipolar plate and (ii) at thermally loaded sites of the bipolar plate. 11 . The fuel cell as claimed in claim 9 , wherein access by at least one of the reactant gases comprising hydrogen and oxygen to the membrane is blocked by a mechanical block disposed between the gas diffusion layer and the membrane in a region of the protrusion. 12 . The fuel cell as claimed in claim 11 , wherein the mechanical block comprises a gas-impermeable film. 13 . The fuel cell as claimed in claim 11 , wherein the mechanical block is contained within pores of the gas diffusion layer. 14 . The fuel cell as claimed in claim 13 , wherein the mechanical block comprises one of (i) an acrylic adhesive and (ii) a fluorothermoplastic. 15 . The fuel cell assembly with at least one proton exchange membrane fuel cell for generating electrical energy from the reactant gases hydrogen and oxygen, comprising: at least one membrane/electrode unit having a membrane and, respectively positioned on each side thereof, a porous gas diffusion layer coated with a platinum electrode; bipolar plates which lie against each gas diffusion layer and through which, during operation, a coolant flows; wherein at least one platinum electrode has a smaller area than the gas diffusion layer; wherein the gas diffusion layer protrudes beyond the platinum electrode for a part of an edge region of the membrane/electrode unit and the gas diffusion layer does not protrude beyond the platinum electrode for another part of the edge region of the membrane/electrode unit; and wherein the edge region is a region around an outer periphery of the membrane/electrode unit. 16 . The fuel cell as claimed in claim 15 , wherein the protrusion of the gas diffusion layer beyond the platinum electrode is provided in one of (i) at a region of a coolant exit from the bipolar plate and (ii) at thermally loaded sites of the bipolar plate. 17 . The fuel cell as claimed in claim 15 , wherein access by at least one of the reactant gases comprising hydrogen and oxygen to the membrane is blocked by a mechanical block disposed between the gas diffusion layer and the membrane in a region of the protrusion. 18 . The fuel cell as claimed in claim 16 , wherein access by at least one of the reactant gases comprising hydrogen and oxygen to the membrane is blocked by a mechanical block disposed between the gas diffusion layer and the membrane in a region of the protrusion. 19 . The fuel cell as claimed in claim 17 , wherein the mechanical block comprises a gas-impermeable film. 20 . The fuel cell as claimed in claim 17 , wherein the mechanical block is contained within pores of the gas diffusion layer. 21 . The fuel cell as claimed in claim 20 , wherein the mechanical block comprises one of (i) an acrylic adhesive and (ii) a fluorothermoplastic. 22 . A method for operating a fuel cell assembly with at least one proton exchange membrane fuel cell for generating electrical energy from the reactant gases hydrogen and oxygen, the method comprising: recessing a platinum electrode and protruding a gas diffusion layer beyond the platinum electrode such that formation of an electrical potential in this part of an edge region of a membrane/electrode unit is prevented for a part of the edge region of the membrane/electrode unit; and ensuring the platinum electrode is not recessed and ensuring the gas diffusion layer does not protrude beyond the platinum electrode such that formation of an electrochemical potential in this part of the edge region of the membrane/electrode unit is not prevented for another part of the edge region of the membrane/electrode unit.