An antenna for use in an RFID tag comprises an antenna yarn. The antenna yarn comprises metal fibers. The metal fibers are stainless steel fibers. The antenna yarn is wrapped by at least one wrapping yarn thereby covering the full surface of the antenna yarn or of the metal wire or of the bundle of metal wires. The at least one wrapping yarn comprises non-electrically conductive fibers.

In an embodiment, the present invention provides a method for producing a structured microfilament non-woven, including: forming a non-woven by spinning microfilaments and/or composite filaments that can be split into microfilaments to form at least one fiber layer, stretching the at least one fiber layer, and laying the at least one fiber layer; thermally pre-bonding the non-woven; treating the thermally pre-bonded non-woven using a pressurized medium in order to break the thermal pre-bonding at least in part; and further applying a pressurized medium to the non-woven while the non-woven is resting on a structure-producing surface, so as to obtain a structured microfilament non-woven.

The invention provides batting that includes a nonwoven web having a first surface parallel to a second surface. The nonwoven web is made up of a fiber mixture that includes: 25 to 75 wt % spiral-crimped siliconized synthetic polymeric fibers having a denier of greater than 4 denier and less than 10 denier; and 20 to 75 wt % down treated with a durable water repellant, said down having a fill power of at least 550 in.sup.3/oz, and having a down cluster content of at least 85 wt %. Articles comprising the batting and methods of making the batting are also provided.

A method of manufacturing multi-ply separable textured yarn, the method comprising, passing a multi-ply separable interlaced filament yarn through a texturizing unit to form a multi-ply separable draw textured yarn, wherein the multi-ply separable interlaced filament yarn is separable in to at least two separable interlaced filament yarn, wherein the interlacing of the filaments within each separable interlaced filament yarn is retained during further processing of the yarn to fabric and in the fabric.

A cloth containing a fiber having on a surface a polyacetal copolymer containing a prescribed amount of oxyalkylene unit(s), wherein the cloth exhibits a q.sub.max value of at least 0.2 W/cm.sup.2, when the cloth is brought into contact with a heat storing plate of 40 C. under a contact pressure of 0.098 N/cm.sup.2 in an environment at a temperature of 20 C. and at a relative humidity of 65%, is superior in contact cold sensation, colorfastness, quick drying property and gloss.

The present disclosure relates to a new and improved textile fabric fabricated of twill weave sheeting that has excellent wrinkle resisting characteristics, improved softness and durability over the sheeting fabrics currently being manufactured, enhanced aesthetic appeal, economy in cost of manufacture and other desirable characteristics. The textile fabric of the present disclosure can be formed of warp and weft yarns of twill weave construction wherein each of the warp yarns can be made of a natural material and each of the weft yarns can be made of a synthetic material. In an embodiment, the twill weave sheeting can have warp yarn and weft yarn, wherein the warp yarn and the weft yarn being a cross weave of cotton and polyester.

A woven fabric with continuous filament, high bulk yarns on the fabric first side is disclosed, and related method and apparatus of manufacturing same.

A first fabric layer of a down-proof double-layer fabric has a plurality of first warps and a plurality of first wefts. A second fabric layer has a plurality of second warps and a plurality of second wefts. The first fabric layer and the second fabric layer have a plurality of coupling portions. In the coupling portions, the first fabric layer and the second fabric layer pass through each other repeatedly, and the first warps and the second warps are interlaced. The first warps, the first wefts, the second warps, and the second wefts are between 20 denier and 75 denier. The warp densities of the first fabric layer and the second fabric layer are between 336 pieces/inch and 456 pieces/inch, and the weft densities of the first fabric layer and the second fabric layer are between 220 pieces/inch and 380 pieces/inch.

A carbon dioxide blocking system is provided comprising a sheeting material treated with a waterproofing agent such that the carbon dioxide blocking system is fully, or nearly fully, impermeable to liquids and gases. The sheeting material may be a microfiber polyester woven sheeting material and the waterproofing agent may be thermoplastic polyurethane. The sheeting material is treated with the waterproofing agent. The treated material comprises a single layer of fabric. The sheeting material provides a soft upper surface, like a sheet, while the waterproofing agent imparts impermeability to the sheeting material such that the carbon dioxide blocking system may serve as a mattress protector to block liquids and also to block the permeability and retention of carbon dioxide to help prevent carbon dioxide rebreathing.

Lightweight, flexible protective fabrics for protecting a person, animal or other object from hot burning materials, hot high heat capacity and/or hot corrosive materials, such as hot molten metal, hot oily liquids (e.g., heating oil), hot gels, hot solids, hot sparks, and hot acids. The lightweight protective fabrics can be used to protect a person, animal or other object from hot molten metals, such as liquid metal zinc heated to a temperature of about 950 F. (510 C.) or greater, hot molten aluminum heated to a temperature of about 1150 F. (620 C.) or greater, burning phosphorus at temperature of about 1550 F. (843 C.) or greater, hot solid iron having a temperature of about 500 F. (260 C.) or greater, hot heating oil having a temperature of about 500 F. (260 C.) or greater, and hot hydrochloric acid having a temperature of about 300 F. (150 C.) or greater.