Embodiments of the present invention relate to flame resistant fabrics formed with inherently flame resistant fibers that provide the requisite thermal and arc protection, that have improved comfort, and that, in some embodiments, are less expensive than other fabrics formed with inherently flame resistant fibers. Improved comfort and lower cost can be achieved by predominantly locating the inherently flame resistant fibers on the front face of the fabric to impart the requisite thermal and arc protection and predominantly locating the more comfortable (and less expensive) fibers on the back face of the fabric positioned next to the wearer. In this way, overall protection of the fabric is maintained while improving comfort. Some embodiments of such fabrics may also achieve NFPA 70E PPE Category 2 protection.

Flame resistant fiber, fabric, including woven, knit, and non-woven fabrics, and clothing incorporating such fibers are provided that include a blend of inherently flame resistant fiber, non-flame resistant fiber, and/or treated flame resistant fiber.

A flame resistant fabric includes first yarns including inherently flame resistant fibers and second yarns including wool fibers. The fabric may satisfy one or more performance standards set forth in ASTM F 1506-02, NFPA 2112 and NFPA 70E. The fabric may be a knit or woven fabric, such as a plush or terry knit construction, and one or both sides of the fabric may be napped to form a fleece fabric. The second yarns may include wool and modacrylic fibers, or wool fibers and other inherently flame resistant fibers. The first yarns or second yarns may include sufficient inherently flame resistant fibers such that the fabric has a char length of no more than 4 inches and an afterflame of no more than 2 seconds when tested in accordance with ASTM D6413. The fabric may exhibit a thermal shrinkage of no more than 10% when tested in accordance with NFPA 2112.

A fabric for use in arc and flame protection, and a process for producing a fire resistant fabric are provided. The fabric is made from at least 70 weight percent (wt %) aramid fiber; less than 40 wt % modacrylic; 8 wt % nylon; and 2 wt % anti-static. The aramid fiber is made from recycled aramid fiber from recycled fire resistant garments, and virgin aramid fiber. The fabric may be used to produce fire-resistant garments worn by workers in many industries such as the oil and gas.

The present invention improves the strength of the bottom (net) of the jig and makes it more difficult and unlikely for deviation of the mesh to occur. A workpiece is loaded on the net (2) of the heat treat furnace jig (hereinafter, heat treatment furnace jig). In the net (2), a first strand (10), a second strand (20) and a third strand (30) are in contact at a contact point (X1). Near the contact point (X1), the second strand (20) overlaps the first strand (10) from above and the third strand (30) overlaps the first strand (10) from below. As a result, the first strand (10) is held between the second strand (20) and the third strand (30) in the up/down directions.

A flame resistant woven fabric has a thickness of 0.08 mm or more in accordance with the method of JIS L 1096-A (2010) and including warps and wefts, the warp and the weft each comprising: a non-melting fiber A having a high-temperature shrinkage rate of 3% or less; and a thermoplastic fiber B having an LOI value of 25 or more in accordance with JIS K 7201-2 (2007) and having a melting point lower than the ignition temperature of the non-melting fiber A; wherein the warp and the weft each have a fracture elongation of 5% or more; and wherein, in the projection area of the weave repeat of the flame resistant woven fabric, the area ratio of the non-melting fiber A is 10% or more and the area ratio of the thermoplastic fiber B is 5% or more.

Flame resistant fabrics that have incorporated into them cellulosic filament yarns. The cellulosic filament yarns may be flame resistant (either inherently FR or treated so as to be FR) or non-flame resistant. Fabrics according to some embodiments are formed entirely of cellulosic filament yarns. However, fabrics according to some embodiments include additional yarns to ensure that the fabric complies with NFPA 1971 and/or 2112.

A fireproof, translucent, flexible coated fabric composite materials for use in fire curtains. The composite material meets or exceeds regulatory requirements in terms of fire endurance and allows transmissivity of necessary amounts of light. The process of the present disclosure combines a silica fabric with a special refractory index controlled resin. This unique combination of materials can transform an opaque high temperature fabric into a translucent, and even transparent, composite which as the ability to resist high temperature, flame and smoke penetration that fills a needed gap in technology between visibility and fire resistance in the field of fire and smoke curtains used in civil construction.

Provided are a method for manufacturing a composite fabric capable of further improving the strength of a carbon fiber-reinforced molded article, a composite fabric, and a carbon fiber-reinforced molded article. The method includes a step of holding a surface of a filter part (22A), through which a dispersion solvent and carbon nanotubes dispersed in the dispersion solvent are allowed to pass, in contact with at least one surface of a woven fabric (12A) including a carbon fiber bundle as weaving yarn, a step of immersing the woven fabric (12A) on which the filter part (22A) is held in a dispersion that comprises the dispersion solvent and the dispersed carbon nanotubes and applying ultrasonic vibrations to the dispersion, and a step of extracting the woven fabric (12A) on which the filter part (22A) is held from the dispersion and removing the filter part (22A) from the woven fabric (12A).

A fabric that includes an air jet core-spun yarn including a core composed of continuous filament thermoplastic yarns and a sheath composed of cellulose staple wrapper fibers or cellulose-rich staple fibers, wherein the fabric is treated with a flame retardant compound.