Embodiments of a leno weave mesh of the present invention generally include a plurality of high-temperature weft yarns, high-temperature warp yarns, and low melting point warp yarns; wherein each low melting point warp yarn is intertwined with a high-temperature warp yarn, each intertwined pair of warp yarns is positioned such that the low melting point warp yarn and high-temperature warp yarn are disposed alternatingly on either side of the woven mesh at intersections of the weft and warp yarns, and the woven mesh is heated whereby the surfaces of the low melting point warp yarns adhere to the surface of the high-temperature warp yarns and said high-temperature weft yarns at contact points there between. An intumescent coating system employing embodiments of the mesh, and a method of providing thermal protection to a substrate utilizing the intumescent coating system, are also provided.

A fabric with carbon nanotube fibers is provided. The fabric has a structure in which warp yarns and weft yarns are interwoven with each other, wherein at least one of the warp yarns and the weft yarns includes carbon nanotube fibers.

A manufacturing method of a fabric with carbon nanotube fibers is provided. The method includes the following steps. Carbon nanotubes are grown on a substrate. A drawing processing is performed on the carbon nanotubes to form carbon nanotube fibers. A spinning processing is performed on the carbon nanotube fibers to form carbon nanotube fiber yarns. A weaving process is performed on the carbon nanotube fiber yarns.

Flame resistant fabrics that have incorporated into them high tenacity long staple yarns formed of long staple fibers. Such high tenacity long staple yarns are less expensive than continuous filament yarns and increase the strength of fabrics that incorporate them as compared to fabrics formed of only spun yarns formed of short staple fibers.

Flame resistant fabrics that have incorporated into them high tenacity long staple yarns formed of long staple fibers. Such high tenacity long staple yarns are less expensive than continuous filament yarns and increase the strength of fabrics that incorporate them as compared to fabrics formed of only spun yarns formed of short staple fibers.

A textile sleeve for routing and protecting an elongate member has a wall including a textile layer with an inner surface and an opposite outer surface extending lengthwise along a central longitudinal axis between opposite ends. The inner surface is configured to bound a cavity sized for receipt of the elongate member therein. The textile layer is formed of yarns interlaced with one another, wherein a least some of the yarns include multifilaments resistant to heat and/or monofilaments resistant to heat, rendering the sleeve heat-resistant. A silicone-based coating is adhered to the outer surface to provide enhanced heat-resistance, dielectric protection and impact resistance.

A textile sleeve for routing and protecting an elongate member has a wall including a textile layer with an inner surface and an opposite outer surface extending lengthwise along a central longitudinal axis between opposite ends. The inner surface is configured to bound a cavity sized for receipt of the elongate member therein. The textile layer is formed of yarns interlaced with one another, wherein a least some of the yarns include multifilaments resistant to heat and/or monofilaments resistant to heat, rendering the sleeve heat-resistant. A silicone-based coating is adhered to the outer surface to provide enhanced heat-resistance, dielectric protection and impact resistance.

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 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 wrappable sleeve for routing and protecting an elongate member, against exposure to high temperature, abrasion, fluid ingress, and contamination, has a multilayered wall extending widthwise between opposite edges and extending lengthwise along a longitudinal axis between opposite ends. The wall includes a textile outer layer, a textile inner layer, and an intermediate layer sandwiched between the outer layer and the inner layer. The intermediate layer includes a textile intermediate layer facing the textile inner layer and a silicone-based layer facing the textile outer layer.