Antimicrobial textiles and methods of making antimicrobial textiles including a sheet substrate comprising a textile and metal oxide nanoparticles in which the nanoparticles are present as a nanocomposite on the surface of and within the sheet substrate. The textiles may be used in wearable items such as personal protective equipment such as face masks. Methods of making the textiles include applying a metal salt solution to a textile to diffuse the metal salt into the textile and drying the textile, such as drying the textile with heat, to bind the metal salt to the surface of and the interior fibers of the textile by forming a nanocomposite of metal nanoparticles or nanostructures in situ.

A method for producing a fiber for reinforcing rubber, comprising applying an adhesion treatment liquid containing a thermoplastic elastomer, a blocked polyisocyanate, and a rubber latex to a fiber cord to obtain a fiber for reinforcing rubber, wherein the thermoplastic elastomer is incorporated in the form of a water dispersion into the adhesion treatment liquid, wherein the thermoplastic elastomer particles in the water dispersion have an average particle diameter of 0.01 to 1.0 ?m.

A fiber-reinforced composite material, consisting of an amorphous thermoplastic matrix distributed over a surface of an aramid fabric and forming a surface thermoplastic film partially interpenetrated with and adhering to the aramid fabric. The production method comprises the steps of: unwinding an aramid fabric on conveyor means; distributing a thermoplastic matrix in the form of micrometric powder over the whole upper surface of the aramid fabric as it is unwound; passing the material through a first hot section and then through a second relatively cold section; the first section applies a temperature and a pressure such as to form a surface thermoplastic film on the fabric; the second section facilitates detachment of the coated material from the conveyor means. The plant comprises a conveyor belt on which an aramid fabric is unwound; a powder scattering station adapted to distribute a thermoplastic matrix in the form of micrometric powder on the aramid fabric as it is unwound on the conveyor belt; a system of double belts in contact through which the fabric is conveyed; the system of double belts in contact defines a first hot section and a second relatively cold section; the first section applies a temperature and a pressure functional to the formation of a surface thermoplastic film on the fabric; the second section facilitates detachment of the fabric.

The present invention relates to textile fibre products having a coating comprising polymers based on ethylenically polymerisable monomers with a glass transition temperature of at least 60 and a coating method for coating fibre products with an aqueous polymer dispersion, wherein an aqueous polymer dispersion based on vinyl polymerisable monomers with a glass transition temperature of at least 60 C. is firstly provided, and this is brought into contact with a fibre product and then dried. The invention also relates to the use of corresponding polymer dispersions for the coating of fibre products, correspondingly coated fiber products, use thereof to reinforce mineral matrices, and corresponding fibre-composite materials, in particular textile-concrete composite materials. In particular, the invention relates to a coating means that can be applied to a textile fabric in a continuous, water-based process and enables an optimal introduction of force from the mineral matrix into the textile reinforcement.

The present invention relates to a surface-modified aramid fiber and a method for preparing the same. The method includes the following steps: modifying an aramid fiber having amino groups and carboxyl groups on the surface with siloxane -glycidoxypropyltrimethoxysilane to obtain a silicon methoxylated aramid fiber; reacting same with a cerium oxide coated with polydopamine modified chaotic boron nitride to obtain a surface-modified aramid fiber. The cerium oxide coated with polydopamine modified chaotic boron nitride has high ultraviolet absorption, and has extremely low catalytic activity, avoiding the damage to a fiber structure by photocatalysis during radiation, being an effective, safe and highly-efficient ultraviolet absorber. The surface-modified aramid fiber provided in the present invention has an ultraviolet-resistant function, high surface activity, good thermal performance, and better mechanical performance, providing excellent overall performance, and having higher utilization value. The method is simple and controllable, being suitable for large scale production.

A braid includes a plurality of metal-plated bundles braided to each other, each of the metal-plated bundle having a flattened shape. Each of the metal-plated bundle includes a plurality of tensile strength fibers, a plurality of first metal plating portions that are formed on the tensile strength fibers respectively, and a second metal plating portion including the first metal plating portions therein, the first metal plating portions having the tensile strength fibers respectively.

The present invention relates to a formaldehyde and resorcinol free dipping solution for cord fabrics and a production method thereof comprising the steps of adding acrylic polymer resin into water (11), adjusting pH value (12), adding epoxy to the composition (13), adding polyisocyanate to the composition (14), adding latex to the composition (15), obtaining the dipping material (16); enabling the synthetic fiber and the rubber used in cord fabric reinforced rubber materials production to be attached to each other by providing an interface between two said materials; not as hazardous as RFL for human health and also being environmentally friendly.

A method for coating a textile material, said method includes the following steps: a) incorporating activated carbon in powder form into a coating composition including an aqueous solvent and at least one organosilicon precursor, wherein the organosilicon precursor represents from 5 to 50% by volume relative to the whole of the aqueous solvent and organosilicon precursor, b) impregnating the textile material with the coating composition by padding and c) drying the impregnated textile material, characterised in that the coating composition contains no polycarboxylic acid or catalyst.

A stab proof material in roll form comprising a matrix distributed over both the surfaces of a textile structure and forming a surface film totally interpenetrated in said textile structure. The production method comprises the steps of: unwinding an aramid fabric on conveyor means; distributing an amorphous thermoplastic matrix starting from a micrometric powder, over both surfaces of the aramid fabric as it is unwound; passing the material through a first hot section and then through a second relatively cold section; the first section applies a temperature and a pressure such as to form an amorphous thermoplastic film on the fabric; the second section facilitates detachment of the coated material from the conveyor means. The plant comprises a conveyor belt on which an aramid fabric is unwound; a powder scattering station adapted to distribute a micrometric powder on the aramid fabric as it is unwound on the conveyor belt; a system of double belts in contact through which the fabric is conveyed; the system of double belts in contact defines a first hot section and a second relatively cold section; the first section applies a temperature and a pressure functional to the formation of an amorphous thermoplastic film on the fabric; the second section facilitates detachment of the fabric.

In a method for producing a PBO fiber with increased resistance against UV-caused degradation, a coating is provided on the PBO fibers, wherein the coating comprises graphene oxide cross-linked by polymerization with glutaraldehyde and resorcinol. The fibers are useful for lighter than air vehicles.