A process for making a composite product comprises the steps of: A. Circumferentially plating a carbon fiber core with an alloy film including a film of high entropy alloy and liquid metal alloy or a film of metallic glass to form a film-clad carbon fiber thread; B. Weaving a plurality of said film-clad carbon fiber threads to form an interlaced film-clad carbon fiber sheet; and C. Vibrationally thermally pressing a plurality of said interlaced film-clad carbon fiber sheets as superimposed with one another to form a composite product.

A process for making a composite product comprises the steps of: A. Circumferentially plating a carbon fiber core with an alloy film including a film of high entropy alloy and liquid metal alloy or a film of metallic glass to form a film-clad carbon fiber thread; B. Weaving a plurality of said film-clad carbon fiber threads to form an interlaced film-clad carbon fiber sheet; and C. Vibrationally thermally pressing a plurality of said interlaced film-clad carbon fiber sheets as superimposed with one another to form a composite product.

A skin care fabric for medical, pharmaceutical or cosmetic use includes at least 80% by weight of microfibers that are a mixture of polyamide and polyester and have a diameter of less than 50 microns. Each microfiber is split to produce fine fibers closely packed in a parallel structure having a capillary effect and an abrasive effect. The fabric has a surface weight of less than 180 g/m.sup.2 and is loaded with medical, pharmaceutical or cosmetic active agents. The skin care fabric includes a warp-knitted fabric having a first surface and a second surface opposite the first surface, which is mechanically roughened and cut to become fluffy and yet short-haired and compact and resulting in a further surface enlargement of the fabric structure and a water absorbency of at least four times the surface weight of the fabric.

A skin care fabric for medical, pharmaceutical or cosmetic use includes at least 80% by weight of microfibers that are a mixture of polyamide and polyester and have a diameter of less than 50 microns. Each microfiber is split to produce fine fibers closely packed in a parallel structure having a capillary effect and an abrasive effect. The fabric has a surface weight of less than 180 g/m.sup.2 and is loaded with medical, pharmaceutical or cosmetic active agents. The skin care fabric includes a warp-knitted fabric having a first surface and a second surface opposite the first surface, which is mechanically roughened and cut to become fluffy and yet short-haired and compact and resulting in a further surface enlargement of the fabric structure and a water absorbency of at least four times the surface weight of the fabric.

The present invention relates to a method for manufacturing a protein fiber, including an extension and contraction step of contracting or extending a protein raw fiber containing a protein by bringing the protein raw fiber into contact with a liquid or vapor; and a drying step of drying the protein raw fiber that has undergone the extension and contraction step while adjusting a length of the protein raw fiber to an arbitrary length.

A fiber is made with a polybenzimidazole (PBI) polymer with a phosphoric acid pick-up (APU) in the range of 1-25% (PBI-p fiber). The PBI-p fiber may have a LOI50% and/or an initial thermal decomposition temperature in air of 555 C. A method of making a phosphonated polybenzimidazole fiber comprises the steps of: spinning an untreated PBI resin into a PBI fiber; treating the PBI fiber with phosphoric acid, and thereby obtaining a PBI fiber with 1-25 wt. % phosphoric acid APU.

A system and method for an energy storing electrical device includes a first conductive electrode, a second conductive electrode, an electrolyte disposed between the first conductive electrode and a second conductive electrode, each electrode further comprising an integrated first layer and a second layer, and; wherein the second layer comprises a substrate, the substrate comprising a textile portion or a polymer portion and a conductive layer formed by a noble metal disposed on and attached to the substrate.

A system and method for an energy storing electrical device includes a first conductive electrode, a second conductive electrode, an electrolyte disposed between the first conductive electrode and a second conductive electrode, each electrode further comprising an integrated first layer and a second layer, and; wherein the second layer comprises a substrate, the substrate comprising a textile portion or a polymer portion and a conductive layer formed by a noble metal disposed on and attached to the substrate.

Chemical compositions and techniques for treating wool (and other animal hair-based) fabrics, and in particular for unshrinking wool fabrics and garments.

Chemical compositions and techniques for treating wool (and other animal hair-based) fabrics, and in particular for unshrinking wool fabrics and garments.