An electrochemical installation operating at high temperature includes a plurality of stacks for carrying out electrochemical reactions, a heating furnace comprising a chamber intended for receiving the stacks, and a heater. The installation includes at least one rack including a self-supporting structure including a plurality of superimposed stages of stacks and/or including a plurality of self-supporting structures defining a plurality of superimposed stages of stacks. Each self-supporting structure comprises a fluid distributor configured to supply each stack with at least one fluid and/or to collect at least one fluid from each stack. The chamber is configured to contain at least one rack, the stack stages of the one rack or each rack contained in the chamber being intended for being commonly heated by the heater.

A sealable volume has a wall forming at least a portion of a boundary limiting the volume. The wall includes a hydrogen permeation barrier including a layer system (LS) having at least one layer. The layer system includes at least one hydrogen barrier layer (HPBL) of an at least ternary oxide. Preferably, the oxide is substantially composed of Al, Cr and O and the hydrogen barrier layer (HPBL) is deposited using physical vapor deposition, in particular cathodic arc evaporation. Preferably, the layer system includes at least one of: an adhesion layer (AdhL), a hydrogen storage layer (HStL), a protective layer (ProtL), in particular a thermal barrier layer (ThBL), a diffusion barrier layer (DBL), an oxidation barrier layer (OxBL), a chemical barrier layer (ChBL), a wear resistance layer (WRL). Excellent hydrogen permeation barrier properties can be achieved, and the layer system can be tailored as required by an envisaged application.

A sealable volume has a wall forming at least a portion of a boundary limiting the volume. The wall includes a hydrogen permeation barrier including a layer system (LS) having at least one layer. The layer system includes at least one hydrogen barrier layer (HPBL) of an at least ternary oxide. Preferably, the oxide is substantially composed of Al, Cr and O and the hydrogen barrier layer (HPBL) is deposited using physical vapor deposition, in particular cathodic arc evaporation. Preferably, the layer system includes at least one of: an adhesion layer (AdhL), a hydrogen storage layer (HStL), a protective layer (ProtL), in particular a thermal barrier layer (ThBL), a diffusion barrier layer (DBL), an oxidation barrier layer (OxBL), a chemical barrier layer (ChBL), a wear resistance layer (WRL). Excellent hydrogen permeation barrier properties can be achieved, and the layer system can be tailored as required by an envisaged application.

A fuel cell includes a cell stack in which multiple unit cells are stacked in a first direction, an enclosure enveloping the cell stack and including at least one opening to open at least one of the two end portions of the cell stack, first and second end plates respectively disposed at the two end portions of the cell stack, a clamping member clamping the unit cells, and a coupling screw coupling the clamping member to a target end plate among the first and second end plates. The target end plate includes a body, including a first internal surface facing the cell stack and an external surface, and a partition wall, spaced from the external surface in the first direction to form a gap. The coupling screw passes through the partition wall and couples the clamping member to the body via the gap.

A fuel cell includes a cell stack in which multiple unit cells are stacked in a first direction, an enclosure enveloping the cell stack and including at least one opening to open at least one of the two end portions of the cell stack, first and second end plates respectively disposed at the two end portions of the cell stack, a clamping member clamping the unit cells, and a coupling screw coupling the clamping member to a target end plate among the first and second end plates. The target end plate includes a body, including a first internal surface facing the cell stack and an external surface, and a partition wall, spaced from the external surface in the first direction to form a gap. The coupling screw passes through the partition wall and couples the clamping member to the body via the gap.

The invention relates to a fuel cell system (100) with at least one fuel cell (90), each fuel cell (90) having a cathode inlet (92), and with a housing (50) in which the at least one fuel cell (90) is arranged, the housing (50) having at least one ventilation inlet (52) through which at least one ventilation fluid flows in and at least one outflow outlet (54) through which at least one outflow fluid flows out. The fuel cell system (100) further comprises a supply line (14) to the at least one cathode inlet (92) for providing a supply fluid from a first fluid source to the at least one cathode inlet (14), and a compressor (16) in the supply line (14) for compressing the supply fluid. The fuel cell system (100) also comprises a fluidly communicating ventilation line (24) between the supply line (14) and the at least one ventilation inlet (52) for connecting the supply line (14) to the at least one ventilation line (52), the fluidly communicating ventilation line (24) being connected to the supply line (14) between the compressor (16) and the at least one cathode inlet (92), and/or a compressor cooling line (32) for cooling the compressor (16) and a fluidly communicating compressor ventilation line (34) between the compressor cooling line (32) and the at least one ventilation inlet (52) for connecting the compressor cooling line (32) to the at least one ventilation inlet (52).

The present invention relates to a cartridge of a fuel cell humidifier and the fuel cell humidifier, the cartridge comprising: an inner case to be inserted into a middle case of the fuel cell humidifier for humidifying dry gas supplied from the outside using wet gas discharged from a fuel cell stack; a plurality of hollow-fiber membranes accommodated inside the inner case; a first potting part which is coupled to the inner case and which fixes one side of each of the hollow-fiber membranes; a second potting part which is coupled to the the inner case and which fixes the other sides of the hollow-fiber membranes; and a link member for connecting the inner case to the middle case so that the middle case and the inner case are linked so as to move according to the pressure of the wet gas positioned inside the middle case.

The present invention relates to a cartridge of a fuel cell humidifier and the fuel cell humidifier, the cartridge comprising: an inner case to be inserted into a middle case of the fuel cell humidifier for humidifying dry gas supplied from the outside using wet gas discharged from a fuel cell stack; a plurality of hollow-fiber membranes accommodated inside the inner case; a first potting part which is coupled to the inner case and which fixes one side of each of the hollow-fiber membranes; a second potting part which is coupled to the the inner case and which fixes the other sides of the hollow-fiber membranes; and a link member for connecting the inner case to the middle case so that the middle case and the inner case are linked so as to move according to the pressure of the wet gas positioned inside the middle case.

A reaction cell for a flow battery having flow channels positioned within a recess of a non-porous and non-brittle housing that is also a dielectric. Positioning the flow channels within the recess eliminates the need for end plates, gaskets, and insulators of conventional designs. A current collector and an electrode within the recess have areas approximately equal to the area of the recess such that they fit within the recess and maximize the contact area between them.

A reaction cell for a flow battery having flow channels positioned within a recess of a non-porous and non-brittle housing that is also a dielectric. Positioning the flow channels within the recess eliminates the need for end plates, gaskets, and insulators of conventional designs. A current collector and an electrode within the recess have areas approximately equal to the area of the recess such that they fit within the recess and maximize the contact area between them.