Methods of making a male touch fastener product, by shearing distal portions of loops extending from a side of a flexible fabric, leaving fibers extending from the side of the flexible fabric in place of the sheared loops, the fibers extending to respective free distal ends, while leaving other loops extending from the side of the fabric intact, and then heating the distal ends with energy supplied by a linear energy source, such that resin of the distal ends flows to form enlarged heads on the extending fibers, while leaving at least some of the other loops intact. A male touch fastener product has a flexible fabric base with a broad side, and fibers extending from the broad side of the base. The fibers form both loops of fibers, each loop extending from the base at two spaced-apart points, and fiber segments extending from the base to respective distal fiber ends spaced from the base. Each distal fiber end forms an enlarged head of fiber resin for snagging other fibers.

Methods of making a male touch fastener product, by shearing distal portions of loops extending from a side of a flexible fabric, leaving fibers extending from the side of the flexible fabric in place of the sheared loops, the fibers extending to respective free distal ends, while leaving other loops extending from the side of the fabric intact, and then heating the distal ends with energy supplied by a linear energy source, such that resin of the distal ends flows to form enlarged heads on the extending fibers, while leaving at least some of the other loops intact. A male touch fastener product has a flexible fabric base with a broad side, and fibers extending from the broad side of the base. The fibers form both loops of fibers, each loop extending from the base at two spaced-apart points, and fiber segments extending from the base to respective distal fiber ends spaced from the base. Each distal fiber end forms an enlarged head of fiber resin for snagging other fibers.

A method includes a preparing step including providing a substrate made of high-density woven cloth, a scouring step including scouring the substrate, a sanforizing step including sanforizing the substrate at a high temperature, a brushing step including brushing the substrate to form a layer of fluff on the substrate, a water repelling treatment step including applying a water repellent on the substrate to fully blend the water repellent into fibers of the substrate, a calendering step including performing a calendering treatment to pressurize the substrate at a high temperature, to shorten and fill a gap between the fibers of the substrate by the fluff, and a waterproof treatment step including applying a waterproof agent on the substrate to form the cleaning cloth.

A method includes a preparing step including providing a substrate made of high-density woven cloth, a scouring step including scouring the substrate, a sanforizing step including sanforizing the substrate at a high temperature, a brushing step including brushing the substrate to form a layer of fluff on the substrate, a water repelling treatment step including applying a water repellent on the substrate to fully blend the water repellent into fibers of the substrate, a calendering step including performing a calendering treatment to pressurize the substrate at a high temperature, to shorten and fill a gap between the fibers of the substrate by the fluff, and a waterproof treatment step including applying a waterproof agent on the substrate to form the cleaning cloth.

A method of making a plant-based deep pile fabric that closely resembles animal fur or wool, that includes extracting the plant fibers from the plant material and forming a yarn or sliver made from plant fibers and simultaneously attaching it to a scrim also made from plant fibers, where the fiber is attached and extends from the scrim to form a length of plant-fiber pile fabric having natural plant fibers on one side and the scrim on the opposite side. The method includes finishing the scrim side of the fabric with an adhesive agent to attach the fibers to the scrim and form a stable base. The method also includes finishing the plant fiber pile side of the fabric by applying fur-industry specific processing steps to alter the properties of the fibers resulting in an even closer resemblance of animal fur.

A method of making a plant-based deep pile fabric that closely resembles animal fur or wool, that includes extracting the plant fibers from the plant material and forming a yarn or sliver made from plant fibers and simultaneously attaching it to a scrim also made from plant fibers, where the fiber is attached and extends from the scrim to form a length of plant-fiber pile fabric having natural plant fibers on one side and the scrim on the opposite side. The method includes finishing the scrim side of the fabric with an adhesive agent to attach the fibers to the scrim and form a stable base. The method also includes finishing the plant fiber pile side of the fabric by applying fur-industry specific processing steps to alter the properties of the fibers resulting in an even closer resemblance of animal fur.

The present invention relates to a functional fabric manufacturing method and a functional fabric thereby, which relates to a method for manufacturing an upcycle functional fabric, comprising steps of: (a) preparing a separator sheet with a microporous structure discarded due to treatment as defective or overproduction in production processes for manufacturing secondary batteries, (b) interposing an adhesive sheet between the separator sheet and a fabric sheet to be added to the separator sheet, thereby supplying each sheet, (c) laminating the separator sheet and the fabric sheet so that they are bonded by melting of the adhesive sheet, wherein in the step (b), each sheet is supplied to maintain a constant tension, but the separator sheet, the adhesive sheet, and the fabric sheet are all supplied at the same speed, and in the step (c), a stacked structure, in which the separator sheet, the adhesive sheet, and the fabric sheet are stacked in this order, is pressurized in a predetermined temperature atmosphere, and laminated.

The present invention relates to a functional fabric manufacturing method and a functional fabric thereby, which relates to a method for manufacturing an upcycle functional fabric, comprising steps of: (a) preparing a separator sheet with a microporous structure discarded due to treatment as defective or overproduction in production processes for manufacturing secondary batteries, (b) interposing an adhesive sheet between the separator sheet and a fabric sheet to be added to the separator sheet, thereby supplying each sheet, (c) laminating the separator sheet and the fabric sheet so that they are bonded by melting of the adhesive sheet, wherein in the step (b), each sheet is supplied to maintain a constant tension, but the separator sheet, the adhesive sheet, and the fabric sheet are all supplied at the same speed, and in the step (c), a stacked structure, in which the separator sheet, the adhesive sheet, and the fabric sheet are stacked in this order, is pressurized in a predetermined temperature atmosphere, and laminated.

Provided is an artificial leather that achieves both a soft texture and excellent durability, and a method for manufacturing the same, the leather comprising: a fibrous base material formed from superfine fibers having an average single fiber diameter of 0.1-10 m; and a polymeric elastic body, where the polymer elastic body comprises a compound having a hydrophilic group and a compound having an ethylene oxide skeleton, the content of the compound in the polymeric elastic body of the artificial leather being 0.1-5 parts by mass per 100 parts by mass of the polymeric elastic body.

Provided is an artificial leather that achieves both a soft texture and excellent durability, and a method for manufacturing the same, the leather comprising: a fibrous base material formed from superfine fibers having an average single fiber diameter of 0.1-10 m; and a polymeric elastic body, where the polymer elastic body comprises a compound having a hydrophilic group and a compound having an ethylene oxide skeleton, the content of the compound in the polymeric elastic body of the artificial leather being 0.1-5 parts by mass per 100 parts by mass of the polymeric elastic body.