A textile sleeve for routing and protecting an elongate member has a wrappable wall including a textile layer having an inner surface and an opposite outer surface extending lengthwise between opposite ends and widthwise between opposite edges. The opposite edges are configured to be wrapped about a central longitudinal axis to bound a central cavity extending lengthwise along the central longitudinal axis between the opposite ends. The textile layer is formed of yarns interlaced with one another, wherein a least some of the yarns include metal wire(s). A silicone-based layer is disposed about the outer surface of the textile layer to provide enhanced heat-resistance, dielectric protection and impact resistance.

A fire protective glove includes a palm portion and a back portion. The palm portion includes a polymer impregnated layer constructed of aramid fibers, leather, or a combination thereof; and a palm moisture barrier layer that is interior to the polymer impregnated layer, the palm moisture barrier layer being constructed of polyurethane, polytetrafluroethylene, aramid fibers, or a combination thereof. The back portion includes a first back protective layer constructed of aramid fibers, leather, or a combination thereof; and a second back protective layer that is interior to the first back protective layer, the second back protective layer being constructed of aramid fibers, modacrylic, or a combination thereof.

Disclosed herein are improved overlapping waterproof seams and methods of producing the same.

Fibers, yarns, woven fabric including the yarns and fibers, and methods of manufacturing the same are disclosed. Fibers can include base material staple fibers and dissolvable or water-soluble fibers. At least the base material staple fiber is mixed and cleaned to form a base material web or sliver. The clean base material web or sliver is then intimately mixed with the dissolvable fibers in a blow room to form a homogenously-mixed base material/dissolvable material sliver. The homogenously-mixed base material/dissolvable material sliver is then blended again during drawing so as to produce a twice-mixed, ultra-homogenous yarn comprising base material and dissolvable material. A processing step can allow for removal of the dissolvable fibers to produce a yarn defining a plurality of pores that are uniformly distributed throughout the structure of the yarn.

Absorbent product including a laminate of at least two plies, wherein the absorbent product has a measured Valley Volume parameter greater than 11 microns and a Pit Density of greater than 25 pockets per sq. cm.

A fiber is a sea-island-type composite fiber in which the primary constituent component of the sea section is an aromatic polyester, the moisture absorption/desorption parameter ΔMR is at least 2.0%, and a diagram obtained by connecting the center of gravity of the islands positioned on the outermost periphery of the fiber cross-sectional surface with line segments is a regular polygon having the center of gravity as an apex. A polyester fiber having superior quality with no splitting of the fiber surface caused by dispersion of stress generated due to volume expansion of the fibers when absorbing moisture, no dyeing irregularity or fuzzing when used in a woven or knitted fabric, and no reduction in moisture absorption due to hot-water processing.

A multi-layered knitted fabric includes: a first layer formed of a first yarn; a second layer formed of a second yarn; and a third layer formed of a third yarn. The first yarn includes an evaporative yarn, the second yarn includes a cut resistant yarn, the third yarn includes an evaporative yarn adapted to allow moisture trapped in the second layer to move to the third layer, and the second layer is arranged between the first and third layers.

A smart (intelligent) textile that can control its porosity, shape, texture, loft, stiffness, or color by temperature change or moisture absorption by using polymer fiber torsional and tensile actuators. This temperature change can be due to a change in ambient temperature or by an external stimulus, such as electrothermal heating. Mechanisms to accomplish this include (a) direct actuation (contraction or expansion) of polymer fiber actuators in a textile structure (b) rotation of polymer fiber actuators helically wrapped around warp and/or weft yarns in a textile structure; (c) rotation of chenille type or ribbon-like warp (or weft) ends by polymer fiber torsional actuators; (d) contraction or expansion of piles or loops in a chenille type fancy yarn produced by using mandrel actuators as pile or loop part of the yarn; (e) buckling of warp (or weft) yarns by contraction of tensile polymer fiber actuators; (f) decrease in yarn diameter by a twisting effect of polymer fiber actuators; (g) contraction or expansion of segmented mandrel actuators with core filament, wire or yarns; or (h) rotation of differentially dyed polymer fiber actuators for color changing textiles.

A single, multi-effect, energy harvesting and heat managing spun yarn and a manufacturing method thereof are provided. The spun yarn includes a combination of a configurable number of fibers selected from a fiber that absorbs, stores, and releases heat energy through a phase change; fibers that convert heat energy or ultraviolet radiation energy into far infrared radiation (FIR) energy and radiate the FIR energy to other fibers and to one or more body parts of a user wearing a garment created from the spun yarn; a fiber that absorbs moisture and generates heat energy through an exothermic reaction; a fiber that provides heat insulation and repels moisture; a fiber with elasticity; and a fiber that conducts heat and maintains a substantially uniform temperature within the fibers. One or more fibers are positioned in a sheath formed free of a core or with at least one core in the spun yarn.

A pre-saturated disposable disinfecting wipe may include a microfiber cloth. The microfiber cloth may include a low weight substrate having a first face and an opposed second face, and microfiber yarn attached to the low weight substrate in a plurality of parallel rows of stitches. The pre-saturated disposable disinfecting wipe further includes a disinfecting formulation saturated in the microfiber cloth. The pre-saturated disposable disinfecting wipe may have a single-touch two-minute wetness coverage of more than 100 in.sup.2. A method of manufacturing a pre-saturated disposable disinfecting wipe may include saturating, with a disinfecting formulation, a microfiber cloth.