Proposed are a high tenacity yarn and a method of manufacturing a glove using the same. More particularly, proposed are a high tenacity yarn capable of being knitted finely and thinly and having a high tenacity even if a metallic yarn is used as a core of a main yarn, and a method of manufacturing a glove using the same. To this end, the high tenacity yarn includes a core yarn and a covering yarn wound on a circumference of the core yarn. The core yarn includes a first core yarn part formed of a metal component and a second core yarn part formed of a metal component, and a total thickness of the first core yarn part and the second core yarn part is formed to be 0.07 mm or less.

Cut-resistant and abrasion-resistant yarns including blends of technical fibers and mineral, inorganic, or ceramic fibers of substantially the same length as the technical fibers, and methods for manufacturing yarns, are disclosed.

Cut-resistant and abrasion-resistant yarns including blends of technical fibers and mineral, inorganic, or ceramic fibers of substantially the same length as the technical fibers, and methods for manufacturing yarns, are disclosed.

Heat resistant separation fabric consisting out of yarns, wherein the yarns comprise metal fibers; wherein the heat resistant fabric comprises boron nitride particles distributed throughout the complete thickness of the fabric; wherein boron nitride particles are present between metal fibers in the yarns; wherein the amount of the boron nitride particles present on the surface of the fabric is not more than the amount of the boron nitride particles present in the bulk of the fabric.

Heat resistant separation fabric consisting out of yarns, wherein the yarns comprise metal fibers; wherein the heat resistant fabric comprises boron nitride particles distributed throughout the complete thickness of the fabric; wherein boron nitride particles are present between metal fibers in the yarns; wherein the amount of the boron nitride particles present on the surface of the fabric is not more than the amount of the boron nitride particles present in the bulk of the fabric.

The present disclosure generally relates to a textile (100) and a manufacturing method (200) thereof. The textile (100) comprises: a fabric body (102) formed from one or more types of yarns; a continuous channel (104) formed within the fabric body (102); and an insulated conductive element (106) disposed within the continuous channel (104), wherein the textile (100) is heatable in response to electrical current being conducted through the insulated conductive element (106).

The present disclosure generally relates to a textile (100) and a manufacturing method (200) thereof. The textile (100) comprises: a fabric body (102) formed from one or more types of yarns; a continuous channel (104) formed within the fabric body (102); and an insulated conductive element (106) disposed within the continuous channel (104), wherein the textile (100) is heatable in response to electrical current being conducted through the insulated conductive element (106).

A machine knittable hybrid yarn for providing conductive traces through a textile is disclosed. The hybrid yarn includes conductive wires coated with an insulating material and twisted together with a nonconductive yarn. The nonconductive yarn is from a strong, inelastic, and nonconductive fiber, such as a meta-aramid or para-aramid that protects the integrity of the conductive wire during knitting. The conductive wire can be copper-clad stainless steel or copper wire is coated with polyurethane, and the nonconductive yarn can have no-drip and no-drip properties to allow ablation of the hybrid yarn to remove the conductive yarn and insulating coating on the wire such that the ablated region becomes externally conductive and suitable for making an electrical contact. The hybrid yarn can be bonded with nylon or similar polymer after twisting.

A machine knittable hybrid yarn for providing conductive traces through a textile is disclosed. The hybrid yarn includes conductive wires coated with an insulating material and twisted together with a nonconductive yarn. The nonconductive yarn is from a strong, inelastic, and nonconductive fiber, such as a meta-aramid or para-aramid that protects the integrity of the conductive wire during knitting. The conductive wire can be copper-clad stainless steel or copper wire is coated with polyurethane, and the nonconductive yarn can have no-drip and no-drip properties to allow ablation of the hybrid yarn to remove the conductive yarn and insulating coating on the wire such that the ablated region becomes externally conductive and suitable for making an electrical contact. The hybrid yarn can be bonded with nylon or similar polymer after twisting.

The present invention provides a colored gold-wrapped thread and a method for making a gold-plated embroidery by using the same, thereby solving the technical problem of single color of a gold-plated embroidery. The method for making a gold-plated embroidery includes preparing embroidery threads, preparing colored gold-wrapped threads and colored gold fixing threads in a mode of one-to-one correspondence of the same color, preparing an embroidery backing material, arranging a to-be-embroidered pattern on the embroidery backing material, preparing embroidery tools, arranging the embroidery backing material on a reel, and embroidering a pattern. The colored gold-wrapped thread includes a thread skin and a wrapped core, where the thread skin is made of a colored glittering silk material having metal luster, and the wrapped core is made of rayon having no twisting strength or a soft and smooth cotton thread.