[Problem to be Solved] To provide a vanadium active material solution which has a vanadium active material concentration of 2.5 M or more in a sulfuric acid solution including a dispersoid (suspensible material), can stably maintain high energy density based on the concentration, and can respond also to fast charge and discharge, and to provide a vanadium redox battery using the active material solution.

[Solution] The above problem is solved by a vanadium active material solution comprising a vanadium compound, which is an active material, as a solute and a dispersoid, wherein the total concentration of vanadium is 2.5 M or more. Here, in a negative electrolyte, the vanadium compound comprises one or both of bivalent and trivalent vanadium. In a positive electrolyte, the vanadium compound comprises one or both of quadrivalent and pentavalent vanadium. In an active material solution, the vanadium compound comprises one or both of trivalent and quadrivalent vanadium. The average diameter of the dispersoid is in the range of 1 nm or more and 100 μm or less.

The invention relates to a device which equips a vehicle that includes a removable container, the device comprising at least one mechanism allowing to clamp the container onto the said vehicle and allowing also to release the container from the said vehicle, by driving a screw or a bolt, screwing to clamp on and unscrewing to unclamp.

A shell reinforcing structure for a fuel cell humidifier comprises a main body shell, fixed plates and grating mechanisms, wherein the side edges of the main body shell are fixedly connected with the fixed plates, the side edge of the fixed plate is provided with an end cover, the upper part of the end cover on the left side is fixedly connected with a dry air inlet tube, the left side of the upper part of the main body shell is fixedly connected with a moisture outlet tube, the right side of the upper part of the main body shell is fixedly connected with a moisture inlet tube, the upper end of the end cover on the right side is fixedly connected with a dry air outlet tube, fixed holes are formed in the side edge surface of the fixed plate.

A shell reinforcing structure for a fuel cell humidifier comprises a main body shell, fixed plates and grating mechanisms, wherein the side edges of the main body shell are fixedly connected with the fixed plates, the side edge of the fixed plate is provided with an end cover, the upper part of the end cover on the left side is fixedly connected with a dry air inlet tube, the left side of the upper part of the main body shell is fixedly connected with a moisture outlet tube, the right side of the upper part of the main body shell is fixedly connected with a moisture inlet tube, the upper end of the end cover on the right side is fixedly connected with a dry air outlet tube, fixed holes are formed in the side edge surface of the fixed plate.

A fuel cell includes a membrane electrode assembly, a separator, a reactant gas channel, a reactant gas manifold, and a buffer portion. The buffer portion includes a first buffer region and a second buffer region. The second buffer region is located in a vicinity of the reactant gas manifold and is deeper than the first buffer region in a stacking direction. Embossed portion groups are arranged in a plurality of rows in the second buffer region between the reactant gas manifold and the first buffer region. Each of the embossed portion groups includes a plurality of embossed portions. A disposition density of the plurality of embossed portions of one of the embossed portion groups in a vicinity of the reactant gas manifold is lower than a disposition density of the plurality of embossed portions of another of the embossed portion groups in a vicinity of the first buffer region.

Microbial fuel cells capable of generating energy from an organic-based fuel are described. The microbial fuel cells can include an anode component, a cathode component, and a separator component selected to reduce spacing between the anode and the cathode thereby improving performance of the microbial fuel cell. Cathode components including particular components that improve the lifetime, performance, and production of the cathode component at reduced cost also are described, as well as a method of using the microbial fuel cells.

Methods and systems are provided for a redox flow battery system. In one example, the redox flow battery is adapted with an additive included in a battery electrolyte and an anion exchange membrane separator dividing positive electrolyte from negative electrolyte. An overall system cost of the battery system may be reduced while a storage capacity, energy density and performance may be increased.

Methods and systems are provided for a redox flow battery system. In one example, the redox flow battery is adapted with an additive included in a battery electrolyte and an anion exchange membrane separator dividing positive electrolyte from negative electrolyte. An overall system cost of the battery system may be reduced while a storage capacity, energy density and performance may be increased.

A cell structure includes a cathode, an anode, and a protonically conductive solid electrolyte layer between the cathode and the anode. The solid electrolyte layer contains a compound having a perovskite structure and containing zirconium, cerium, and a rare-earth element other than cerium. If the solid electrolyte layer has a thickness of T, the elemental ratio of zirconium to cerium at a position 0.25 T from a surface of the solid electrolyte layer opposite the cathode, Zr.sub.C/Ce.sub.C, and the elemental ratio of zirconium to cerium at a position 0.25 T from a surface of the solid electrolyte layer opposite the anode, Zr.sub.A/Ce.sub.A, satisfy Zr.sub.C/Ce.sub.C>Zr.sub.A/Ce.sub.A, and Zr.sub.C/Ce.sub.C>1.

The purpose of the present invention is to provide: a method for producing a gas diffusion electrode base which enables the achievement of a gas diffusion electrode base that has a microporous layer with small surface roughness and is not susceptible to damaging an electrolyte membrane; and a gas diffusion electrode base that has a microporous layer with small surface roughness and is not susceptible to damaging an electrolyte membrane. For the purpose of achieving the above-described purpose, the present invention has the configuration described below. Namely, a specific gas diffusion electrode base which has a carbon sheet and a microporous layer, and wherein the carbon sheet is porous and the DBP oil absorption of a carbon powder contained in the microporous layer is 70-155 ml/100 g.