A porous material with a specific surface area higher than 10/mm, and methods and system for manufacturing such a porous material. The porous material includes a plurality of pores having a substantially uniform size with a variation of less than about 20%, wherein the size is larger than about 100 nm and smaller than about 5 mm. A system including the porous material can be configured as one of a desalination system, a super-fine bubble generation system, a capacitor system, or a battery system.

A method for producing an electrodeposition coated article, in which an insulating film is formed by forming an insulating layer on a surface of an article to be coated according to an electrodeposition method by using an electrodeposition coating material, and then by performing a baking treatment, the electrodeposition coating material contains a solvent containing polyamide imide and an organic solvent added to the electrodeposition coating material, a boiling point of the organic solvent is higher than 100° C., and a Hansen solubility parameter is similar to the polyamide imide and has high compatibility.

A method for producing an electrodeposition coated article, in which an insulating film is formed by forming an insulating layer on a surface of an article to be coated according to an electrodeposition method by using an electrodeposition coating material, and then by performing a baking treatment, the electrodeposition coating material contains a solvent containing polyamide imide and an organic solvent added to the electrodeposition coating material, a boiling point of the organic solvent is higher than 100° C., and a Hansen solubility parameter is similar to the polyamide imide and has high compatibility.

The present disclosure discloses a continuous electrophoretic deposition modified carbon fiber reinforced multi-matrix composite and a preparation method thereof, composing of a carbon fiber with a volume fraction of 30-55%, an inorganic powder with a volume fraction of 3-25% and a matrix with a volume fraction of 20-67%, wherein the inorganic powder is wrapped on the surface of the carbon fiber filament or embedded in the carbon fiber bundle, and the concentration gradually decreases from the fiber filament to the surface of the fiber bundle. The preparation method of the composite is as follows: (1) pretreating the carbon fibers; (2) preparing a slurry of the inorganic powder; (3) widening the pretreated carbon fiber to form a carbon fiber strip, and then carrying out electrophoretic deposition on the inorganic powders; (4) preparing a preform from the deposited carbon fibers; and (5) compounding a matrix in the preform.

The present disclosure discloses a continuous electrophoretic deposition modified carbon fiber reinforced multi-matrix composite and a preparation method thereof, composing of a carbon fiber with a volume fraction of 30-55%, an inorganic powder with a volume fraction of 3-25% and a matrix with a volume fraction of 20-67%, wherein the inorganic powder is wrapped on the surface of the carbon fiber filament or embedded in the carbon fiber bundle, and the concentration gradually decreases from the fiber filament to the surface of the fiber bundle. The preparation method of the composite is as follows: (1) pretreating the carbon fibers; (2) preparing a slurry of the inorganic powder; (3) widening the pretreated carbon fiber to form a carbon fiber strip, and then carrying out electrophoretic deposition on the inorganic powders; (4) preparing a preform from the deposited carbon fibers; and (5) compounding a matrix in the preform.

Provided is an electrodeposition dispersion including a polyamide-imide resin, a polar solvent, water, a poor solvent, and a base, in which the polar solvent is an organic solvent having a boiling point of higher than 100° C. and D.sub.(S-P) represented by a formula (1) satisfying a relationship of D.sub.(S-P)<6, and a weight-average molecular weight of the polyamide-imide is 10×10.sup.4 to 30×10.sup.4 or a number-average molecular weight of the polyamide-imide is 2×10.sup.4 to 5×10.sup.4.
D.sub.(S-P)=[(dD.sup.S−dD.sup.P).sup.2+(dP.sup.S−dP.sup.P).sup.2+(dH.sup.S−dH.sup.P).sup.2].sup.1/2  (1)

Provided is an electrodeposition dispersion including a polyamide-imide resin, a polar solvent, water, a poor solvent, and a base, in which the polar solvent is an organic solvent having a boiling point of higher than 100° C. and D.sub.(S-P) represented by a formula (1) satisfying a relationship of D.sub.(S-P)<6, and a weight-average molecular weight of the polyamide-imide is 10×10.sup.4 to 30×10.sup.4 or a number-average molecular weight of the polyamide-imide is 2×10.sup.4 to 5×10.sup.4.
D.sub.(S-P)=[(dD.sup.S−dD.sup.P).sup.2+(dP.sup.S−dP.sup.P).sup.2+(dH.sup.S−dH.sup.P).sup.2].sup.1/2  (1)

The invention relates to an installation for impregnating powder on at least one substrate to be treated of the yarn and/or tape type. The installation includes a powder delivery unit, a unit supplying the substrate to be treated, at least two electrodes and a circulation zone for the powder and the substrate to be treated. The installation also includes a containment unit having an inlet orifice for the substrate to be treated and the powder, an outlet orifice for the impregnated substrate and a contour area closed from the inlet orifice to the outlet orifice. The circulation zone is formed by the internal volume of the containment unit, and the confinement unit is fixed with respect to at least one of the electrodes. The substrate to be treated and the powder are mobile, in the circulation zone, between the inlet orifice and the outlet orifice of said confinement unit.

The invention relates to an installation for impregnating powder on at least one substrate to be treated of the yarn and/or tape type. The installation includes a powder delivery unit, a unit supplying the substrate to be treated, at least two electrodes and a circulation zone for the powder and the substrate to be treated. The installation also includes a containment unit having an inlet orifice for the substrate to be treated and the powder, an outlet orifice for the impregnated substrate and a contour area closed from the inlet orifice to the outlet orifice. The circulation zone is formed by the internal volume of the containment unit, and the confinement unit is fixed with respect to at least one of the electrodes. The substrate to be treated and the powder are mobile, in the circulation zone, between the inlet orifice and the outlet orifice of said confinement unit.

The present invention is directed toward a coating system for electrodepositing a battery electrode coating onto a foil substrate, the system comprising a tank structured and arranged to hold an electrodepositable coating composition; a feed roller positioned outside of the tank structured and arranged to feed the foil into the tank; at least one counter electrode positioned inside the tank, the counter electrode in electrical communication with the foil during operation of the system to thereby deposit the battery electrode coating onto the foil; and an in-line foil drier positioned outside the tank structured and arranged to receive the coated foil from the tank. Also disclosed are methods for electrocoating battery electrode coatings onto conductive foil substrates, coated foil substrates, and electrical storage devices comprising the coated foil substrates.