Provided herein are energy storage device electrode films comprising a hybrid electrode film, and methods of forming such multilayer hybrid electrode films and energy storage devices comprising multilayer hybrid electrode films. Each hybrid electrode film may comprise a self-supporting dry coated active layer and a wet cast active layer, wherein each active layer comprises a binder and an active material. The binder and/or active material may be the same or different as any other active layer. The hybrid multilayer electrode film may further comprise at least one additional layer, and the hybrid multilayer electrode film may be laminated with a current collector to form an electrode.

A device for manufacturing a membrane-electrode assembly for a fuel cell may include top and bottom side bonding rolls respectively disposed above and below a transfer path through which an electrolyte membrane and top and bottom electrode films transferred with a predetermined line speed, one of the top side and bottom side bonding rolls provided reciprocally movable in a vertical direction through a first driving source, and transfer anode and cathode catalyst electrode layers of the top and bottom electrode films to top and bottom sides of the electrolyte membrane while compressing the top and bottom electrode films; film rewinders provided above and below the transfer path to rewind the top and bottom electrode films; and a compulsive driving roll provided in a rewinding path of an electrode film rewound by one of the film rewinders and selectively compulsively feeding the electrode film with a predetermined driving speed.

The present invention proposes an electrode thin film and a method for manufacturing the electrode thin film. The method includes: determining a height between a first roller and a substrate and a coating speed for the first roller coating a first metal nanowire suspension liquid onto the substrate based on a suspension property of the first metal nanowire suspension liquid; coating, by using the first roller, the first metal nanowire suspension liquid onto the substrate with the coating speed to form a wetting film on the substrate; and controlling a first temperature of the substrate heating the wetting film based on the suspension property of the first metal nanowire suspension liquid to dry the wetting film as the electrode thin film. The first temperature makes a dewetting speed of the wetting film higher than a drying speed of the wetting film.

A dual fiber mat for making an electrode includes first nanofibers and second nanofibers. The first fibers contain particles for electrochemical reaction and a binder. The second fibers contain particles for electron conduction and a binder. For a Li-ion battery anode, the first fibers include a polymer binder composed of an electron conducting polyfluorene derivative polymer (PFM or PEFM) or PVDF or PAA and silicon nanoparticles or silicon nanorods embedded in the binder. For a Li-ion battery cathode, the first fibers include a binder composed of an electron conducting polymer (PFM or PEFM) or PAA or PVDF and LiCoO2 or LiFePO4 or Li2MnO3 particles embedded in the binder. The second nanofibers include a PFM or PEFM binder or non-conductive polymer binder and electrically conductive nanoparticles embedded in the binder. The dual fiber mat has a thickness in a range of about 50-1000 m.

A method of fibrillizing a fibrillizable binder component of an electrode film can include providing a negatively charged fibrillizable binder component, and applying an electric field upon the negatively charged binder component to fibrillize the negatively charged fibrillizable binder component. A system for fibrillizing a binder component of an electrode film can include a mixing container made of a material having an affinity to donate electron(s) to the binder component, and an actuator configured to apply a force upon the mixing container so as to contact the mixing container with the binder component and to move the mixing container and the binder component relative to each other within a speed and range of motion sufficient to create an electrostatic force on the binder component and fibrillize the binder component.

The invention relates to an oxygen-consuming electrode, in particular for use in chloralkali electrolysis, comprising a novel catalyst coating based on carbon nanotubes and a silver-based cocatalyst, and to an electrolysis device. The invention further relates to a method for producing said oxygen-consuming electrode and to the use thereof in chloralkali electrolysis or fuel cell technology.

Dry process based energy storage device structures and methods for using a dry adhesive therein are disclosed.

The present disclosure relates to a positive electrode for lithium air batteries, a method of manufacturing the positive electrode, and a lithium air battery including the positive electrode, and more particularly to a positive electrode for lithium air batteries, wherein the positive electrode is manufactured through a dry process instead of a conventional wet process and a mixture of a positive electrode active material and a binder is ball-milled under specific conditions, thereby reducing or preventing a swelling phenomenon due to a solvent and increasing the force of coupling between the positive electrode active material and the binder, whereby it is possible to manufacture a high-density electrode and to improve the durability of the electrode, and wherein the lifespan of a lithium air battery is increased when the positive electrode is applied to the battery.

The processing apparatus includes: a first roller 10 around which a gas-diffusion layer sheet (carbon paper CP) is wound, the gas-diffusion layer sheet being an electrically conductive porous member; a second roller 20 configured to take up the carbon paper CP wound around the first roller 10; and a processing oven configured to heat process a portion of the carbon paper CP, the portion having been fed from the first roller 10 but not yet taken up by the second roller 20. A heat-resistant lead LE is provided, the heat-resistant lead LE having a length at least extending from the first roller 10 to the second roller 20 through the processing oven, being configured to be taken up by the second roller 20, and being bonded to the carbon paper CP impregnated with a thermosetting resin AD.

An assembly apparatus for a membrane-electrode-gas diffusion layer-assembly for a cell for fuel cell capable of positioning and assembling materials while suppressing failures is provided. An assembly apparatus includes a pair of transfer rollers, a first detection unit, a second detection unit, and a conveyance unit. The conveyance unit includes a pair of first rollers and a pair of second rollers. The pair of first rollers are arranged to be separated in a width direction of a band-shaped sheet intersecting with a conveying direction, and rotate in contact with the preliminary assembly. The pair of second rollers are arranged to be separated in the width direction, and rotate while sandwiching the preliminary assembly with the pair of first rollers. An inclination at least one of the first roller or the second roller varies with respect to the conveying direction together with the preliminary assembly.