A separator assembly for a fuel cell having an anode separator, a cathode separator, a cooling surface frame, and a gasket. In particular, the cooling surface frame is integrally bonded between peripheral portions of the anode separator and the cathode separator. Additionally, the gasket encloses the peripheral portions of the anode separator and the cathode separator between which the cooling surface frame is interposed.

Methods and apparatus to form biocompatible energization elements are described. In some embodiments, the methods and apparatus to form the biocompatible energization elements involve forming cavities into a fuel cell. The active elements of a cathode, anode, membrane and fuel storage are sealed with a laminate stack of biocompatible material. In some embodiments, a field of use for the methods and apparatus may include any biocompatible device or product that requires energization elements.

Methods and apparatus to form biocompatible energization elements are described. In some embodiments, the methods and apparatus to form the biocompatible energization elements involve forming cavities into a fuel cell. The active elements of a cathode, anode, membrane and fuel storage are sealed with a laminate stack of biocompatible material. In some embodiments, a field of use for the methods and apparatus may include any biocompatible device or product that requires energization elements.

A system for inspecting quality of a membrane-electrode assembly (MEA) of a fuel cell includes a bonding device configured to bond the MEA and a gas diffusion layer (GDL) to manufacture a bonded unit thereof. A transfer device adsorbs one surface of the bonded unit to transfer the bonded unit. An inspection device is disposed on one side of the bonded unit transferred by the transfer device and inspects an outer appearance of the bonded unit. A reversing device places the bonded unit thereon by the transfer device and reverses the bonded unit vertically. A loading and lifting device loads the bonded unit thereon after being transferred by the transfer device and adjusts a loading height.

A system for inspecting quality of a membrane-electrode assembly (MEA) of a fuel cell includes a bonding device configured to bond the MEA and a gas diffusion layer (GDL) to manufacture a bonded unit thereof. A transfer device adsorbs one surface of the bonded unit to transfer the bonded unit. An inspection device is disposed on one side of the bonded unit transferred by the transfer device and inspects an outer appearance of the bonded unit. A reversing device places the bonded unit thereon by the transfer device and reverses the bonded unit vertically. A loading and lifting device loads the bonded unit thereon after being transferred by the transfer device and adjusts a loading height.

A method of suctioning a gasket main body with a suction jig to separate the gasket main body from a carrier film. The method separates a gasket main body from a carrier film in a gasket including a combination of the gasket main body and the carrier film adhered thereto, where a suction jig is used to separate the carrier film and the gasket main body; the suction jig includes a suction surface at a position facing the carrier film; the suction surface being formed with a suction groove having a shape that corresponds with a planar shape of the gasket main body, the suction groove being formed with a plurality of suction paths across the entire periphery; and the gasket main body is suctioned to the suction groove with the suction force from the suction paths in the suction jig and separated from the carrier film.

A method of suctioning a gasket main body with a suction jig to separate the gasket main body from a carrier film. The method separates a gasket main body from a carrier film in a gasket including a combination of the gasket main body and the carrier film adhered thereto, where a suction jig is used to separate the carrier film and the gasket main body; the suction jig includes a suction surface at a position facing the carrier film; the suction surface being formed with a suction groove having a shape that corresponds with a planar shape of the gasket main body, the suction groove being formed with a plurality of suction paths across the entire periphery; and the gasket main body is suctioned to the suction groove with the suction force from the suction paths in the suction jig and separated from the carrier film.

A microseal for a metal bead seal joint includes a substantially horizontal surface, first and second substantially vertical surfaces disposed on opposite ends of the substantially horizontal surface, and a contoured surface operatively configured to adhere to a portion of a metal bead. The contoured surface may be disposed opposite the substantially horizontal surface and may be integral to the first and second substantially vertical surfaces. The substantially horizontal surface may be operatively configured to substantially maintain its horizontal surface orientation in both a compression state and a non-compression state.

A microseal for a metal bead seal joint includes a substantially horizontal surface, first and second substantially vertical surfaces disposed on opposite ends of the substantially horizontal surface, and a contoured surface operatively configured to adhere to a portion of a metal bead. The contoured surface may be disposed opposite the substantially horizontal surface and may be integral to the first and second substantially vertical surfaces. The substantially horizontal surface may be operatively configured to substantially maintain its horizontal surface orientation in both a compression state and a non-compression state.

The invention relates to a method for producing a metal-supported fuel cell and/or electrolyzer unit, in particular a metal-supported solid oxide fuel cell unit, wherein the metal-supported fuel cell and/or electrolyzer unit comprises at least one electrode unit (14a; 4b; 14c; 14f) with at least two functional layers (16a, 18a;16b, 18b;16c, 8c; 16f, 18f), and the metal-supported fuel cell and/or electrolyzer unit comprises at least one metal support device for supporting the electrode unit (14a; 14b; 14c; 14f). According to the invention, the metal support device and the electrode unit (14a; 14b; 14c; 14f) which has the at least two functional layers (16a, 8a; 16c, 18c; 16f, 18f) are produced separately.