Herein is disclosed, a rechargeable flow battery, wherein the flow battery comprises: first and second electrodes, separated such that ions are allowed to flow between them, wherein a first reservoir comprising or for holding a first fluid electrolyte is fluidly connected to the first electrode, to allow circulation of the first fluid electrolyte from the first reservoir to the first electrode and from the first electrode to the first reservoir; and a first current collector comprising a layer of electrically conductive material having opposing first and second sides, wherein the first electrode is disposed on the first side of the first current collector, such that electrons can flow from the electrode to the first current collector, and a first layer of dielectric material is disposed on the second side of the first current collector.

A microwatt fuel cell stack that demonstrates a wide range temperature tolerance, low reactant cross-over and leakage, low internal leakage current, and/or effective water transport is disclosed. Both H.sub.2 and O.sub.2 may be supplied directly to the fuel cell stack (i.e., dead-ended). One-piece gas diffusion electrodes (GDEs) may serve as both the active electrode and manifold port. Water removal may be accomplished by permeation through the membrane to “fins” exposed by notches in the bipolar plates and gaskets.

A fuel cell system conduit assembly includes a dielectric tube having a first end and a second end, a metallic first flange press-fit to the first end of the dielectric tube, a metallic second flange press-fit to the second end of the dielectric tube, a first snap ring disposed between the first flange and the dielectric tube, and a second snap ring disposed between the second flange and the dielectric tube.

The invention relates to a joint structure including a continuous joined section that joins together a pair of thin plates layered on each other so as to seal a space between the pair of the thin plates surrounded by the joined section, in which the joined section includes at least one continuous joining line which intersects plural times, and a plurality of spatial areas surrounded by two adjacent intersections of the joining line and the joining line connecting the two intersections.

A separator is stacked on each of both surfaces of a membrane electrode assembly to form a fuel cell. This separator includes a base part extending in the form of a surface, and a bead continuous with the base part and protruding from the base part in a stacking direction. The bead includes, in plan view, a straight section extending straight and a curved section continuous with the straight section and curved from the straight section. In the separator, the height from the base part to a top part of the curved section is configured to be lower than the height from the base part to a top part of the straight section.

Implementation of an interconnector structure for an SOEC or SOFC electrochemical device, the interconnector being formed of a conductive support element having a first face with a rough region, the roughness of which has been modified locally before being brought into contact with a seal.

A redox flow battery includes: a battery cell including a positive electrode, a negative electrode, and a membrane interposed between the positive electrode and the negative electrode; a pair of cell frames each including a bipolar plate and a frame body surrounding a circumferential edge of the bipolar plate, the pair of cell frames holding the battery cell therebetween; a positive electrolyte supplied to the positive electrode; and a negative electrolyte supplied to the negative electrode. The bipolar plate is formed of pure titanium or a titanium alloy, and the negative electrolyte has an oxidation-reduction potential of 0.0 V or higher relative to a standard hydrogen electrode.

Herein is disclosed, a rechargeable flow battery, wherein the flow battery comprises: first and second electrodes, separated such that ions are allowed to flow between them, wherein a first reservoir comprising or for holding a first fluid electrolyte is fluidly connected to the first electrode, to allow circulation of the first fluid electrolyte from the first reservoir to the first electrode and from the first electrode to the first reservoir; and a first current collector comprising a layer of electrically conductive material having opposing first and second sides, wherein the first electrode is disposed on the first side of the first current collector, such that electrons can flow from the electrode to the first current collector, and a first layer of dielectric material is disposed on the second side of the first current collector.

An assembly includes an SOEC/SOFC-type solid oxide stack, a clamping system for clamping the stack, including at least two clamping rods that can be used to assemble upper and lower clamping plates, and a coupling system for high-temperature fluid-tight coupling of the stack to a heating system for supplying and discharging gas. The coupling system includes a collector with collection ducts for supplying and discharging gas, each provided with a collecting port positioned facing a corresponding communication port of at least one of the upper and lower clamping plates, and seals each placed between a collecting port and a corresponding communication port.

A plate includes a planar portion and a circular bead, or circular bead seal, that is offset from the planar portion. An axis is substantially perpendicular to the planar portion, and the circular bead arcs about the axis. The axis may be defined by a hole through the planar portion that is substantially surrounded by the circular bead. One or more displacement absorption tunnels is offset from the planar portion and extends radially relative to the axis. Each of the displacement absorption tunnels intersects the circular bead. In some configurations the displacement absorption tunnels may have an arcuate shape, and in some configurations the displacement absorption tunnels may have a trapezoidal shape. A plurality of plates having similar, though not identical, features may be stacked together.