A lithium-ion battery separator with high-temperature resistance, a preparation method thereof and a lithium-ion battery prepared therefrom fall within the field of lithium-ion battery separators. The separator has a thickness of 3.5-30 μm, a porosity of 30-80%, an adjustable pore size of 20-2000 nm, a biaxial tensile strength of ≥50 MPa, an air permeability of ≤400 s/100 cc, and a breaking temperature of ≥160° C. The preparation method comprises the following steps: mixing, melting, and plasticizing 20%-60% of a polypropylene main material, 2%-10% of a solubilizer, 30%-80% of a solvent. 0.1%-5% of a nucleating aid and/or 0.1%-1% of an antioxidant, carrying out twin-screw extrusion, carrying out thermally induced phase separation to obtain a cast sheet, and carrying out cast sheet stretching, extraction, and post-treatment or directly carrying out extraction and post-treatment. The separator has the characteristics of high-temperature resistance, biaxial high strength, uniform pore size, high specific resistance.

Disclose are is method of manufacturing a ventilation sheet for a vehicle. The ventilation sheet for a vehicle is manufactured by performing anti-fouling finishing treatment using an anti-fouling coating agent including an anti-fouling composition. The anti-fouling properties can be improved to prevent the sheet from being fouled, and flame-retardant treatment is performed through a flame-retardant aqueous solution including flame-retardant PET fiber and flame retardant in bath so that the deterioration of flame retardancy caused by the improved anti-fouling properties can be prevented through the flame-retardant treatment while ventilation properties are maintained.

The present invention provides a crosslinked molded article having a lower compression set; and a method for producing a crosslinked molded article by injection molding, the method enabling shortening of one cycle in injection molding, the method being suitable for obtaining a crosslinked molded article having a lower compression set. The present invention relates to a method for producing a crosslinked molded article, comprising melt-kneading a polymer composition containing a polymer having a terminal double bond, a hydrosilyl group-containing compound (Y) having at least two hydrosilyl groups per molecule, a platinum-based catalyst (Z) for hydrosilicon crosslinking, and a reaction inhibitor (D), subjecting the polymer composition to injection molding in a mold, performing primary crosslinking in the mold, removing the primary-crosslinked molded article from the mold, and then performing secondary crosslinking in a heat medium.

Disclosed herein are polymer-based films (and articles of manufacture made therefrom or comprising thereof). In several embodiments, the film comprises biodegradable polymers. In several embodiments, the film comprises post-consumer recycled material. In several embodiments, the film comprises an odor absorbing agent (e.g., carbon). In several embodiments, an article of manufacture comprising a film as disclosed herein or the film itself is biodegradable.

This invention involves a cost effective antiviral plastic film with variable physical properties, comprising of at least one thinner surface layer to minimize the amount of the expensive copper nano-powders required to render the film to be antiviral, and one thicker substrate layer with variable physical properties and thickness. The plastic film is made using a co-extrusion cast film or a blown film process so that the antiviral surface layer and the substrate are joined together as they are made into a multilayer film. The physical properties for the plastic film can be varied by using different kinds of polymeric materials such as PE, PP, PVC, Nylons and others. Its low cost combined with variable physical properties make our invented film suitable for making a wide variety of affordable and safer protection products against the COVID-19. Such products include gloves, masks, covers, wrappers, curtains, bags and protective apparels, for use by individuals, healthcare facilities, restaurants and other industries.

The present invention provides a crosslinked molded article having a lower compression set; and a method for producing a crosslinked molded article by injection molding, the method enabling shortening of one cycle in injection molding, the method being suitable for obtaining a crosslinked molded article having a lower compression set. The present invention relates to a method for producing a crosslinked molded article, comprising melt-kneading a polymer composition containing a polymer having a terminal double bond, a hydrosilyl group-containing compound (Y) having at least two hydrosilyl groups per molecule, a platinum-based catalyst (Z) for hydrosilicon crosslinking, and a reaction inhibitor (D), subjecting the polymer composition to injection molding in a mold, performing primary crosslinking in the mold, removing the primary-crosslinked molded article from the mold, and then performing secondary crosslinking in a heat medium.

A product capable of controlling odours arising from organic matter, and a method of making the product. The product comprises an admixture of a moldable thermoplastic and a benign dormant bacteria in a sporulated form, which admixture is formed by mixing the benign dormant bacteria into the moldable thermoplastic when the moldable thermoplastic is melted, and molding the admixture into a molded product. The benign dormant bacteria are embedded throughout the molded product, including being buried within a body of the molded product and being presented on a surface of the molded product. The benign dormant bacteria presented on the surface of the molded product are activatable upon exposure of the surface of the molded product to the organic matter, and the benign activated bacteria digest the organic matter to control production of offensive odours. Abrasive wear of the surface of the molded product exposes fresh benign dormant bacteria buried in the body to the surface for additional odour control.

A product capable of controlling odors arising from organic matter, and a method of making the product. The product comprises an admixture of a moldable thermoplastic and a benign dormant bacteria in a sporulated form, which admixture is formed by mixing the benign dormant bacteria into the moldable thermoplastic when the moldable thermoplastic is melted, and molding the admixture into a molded product. The benign dormant bacteria are embedded throughout the molded product, including being buried within a body of the molded product and being presented on a surface of the molded product. The benign dormant bacteria presented on the surface of the molded product are activatable upon exposure of the surface of the molded product to the organic matter, and the benign activated bacteria digest the organic matter to control production of offensive odors. Abrasive wear of the surface of the molded product exposes fresh benign dormant bacteria buried in the body to the surface for additional odor control.

A lithium-ion battery separator with high-temperature resistance, a preparation method thereof and a lithium-ion battery prepared therefrom fall within the field of lithium-ion battery separators. The separator has a thickness of 3.5-30 m, a porosity of 30-80%, an adjustable pore size of 20-2000 nm, a biaxial tensile strength of 50 MPa, an air permeability of 400 s/100 cc, and a breaking temperature of 160 C. The preparation method comprises the following steps: mixing, melting, and plasticizing 20%-60% of a polypropylene main material, 2%-10% of a solubilizer, 30%-80% of a solvent. 0.1%-5% of a nucleating aid and/or 0.1%-1% of an antioxidant, carrying out twin-screw extrusion, carrying out thermally induced phase separation to obtain a cast sheet, and carrying out cast sheet stretching, extraction, and post-treatment or directly carrying out extraction and post-treatment. The separator has the characteristics of high-temperature resistance, biaxial high strength, uniform pore size, high specific resistance.

A manufacturing method of a fiber includes: mixing and stirring a plurality of raw materials, to form a mixed liquid, where the plurality of raw materials includes dry copper nanopowder with a particle size not more than 48 nm, a fiber slurry, and an additive; drying the mixed liquid, to remove moisture of the mixed liquid and form a processed raw material; heating the processed raw material, to make the processed raw material be in a semi-molten state; electrifying the processed raw material in the semi-molten state, and then extruding at least one fibril from the processed raw material in the semi-molten state; stretching the at least one fibril; and performing cooling and shaping on at least one stretched fibril, to form a final fiber product.