A system for embroidering a flame-resistant emblem uses flame-resistant threads for both the primary thread and the bobbin thread, as well as any accompanying supplemental fabrics. The flame-resistant primary thread protects the embroidered portion of the underlying material from any direct flame exposure. The flame-resistant bobbin thread ensures that the embroidered pattern cannot fall off of a garment, further flameproofing both the garment and present invention. Furthermore, a backing may be provided as a mechanism for providing a stitchwork surface and for adding dimensionality to the pattern. The backing may also be made of fireproof threads. The apparatus may also be utilized for appending a flame-resistant patch or patches onto a garment. Such a mechanism allows for attachment of flame-resistant threadwork onto any clothing. The primary thread, bobbin thread, backing, and any other additional threads may utilize fire-resistant aramid fibers, which sufficiently fireproofs garments before deployment into potential fire exposure.

A system for embroidering a flame-resistant emblem uses flame-resistant threads for both the primary thread and the bobbin thread, as well as any accompanying supplemental fabrics. The flame-resistant primary thread protects the embroidered portion of the underlying material from any direct flame exposure. The flame-resistant bobbin thread ensures that the embroidered pattern cannot fall off of a garment, further flameproofing both the garment and present invention. Furthermore, a backing may be provided as a mechanism for providing a stitchwork surface and for adding dimensionality to the pattern. The backing may also be made of fireproof threads. The apparatus may also be utilized for appending a flame-resistant patch or patches onto a garment. Such a mechanism allows for attachment of flame-resistant threadwork onto any clothing. The primary thread, bobbin thread, backing, and any other additional threads may utilize fire-resistant aramid fibers, which sufficiently fireproofs garments before deployment into potential fire exposure.

A protective garment comprises a thermal liner, a moisture barrier, and an outer shell. The protective garment includes one or more transferal portions located at predetermined areas to enhance evaporative heat transfer. In some embodiments, the transferal portions of the protective garment have Resistance to Evaporation of a Textile (Ret) of less than 20 m2 Pa/W.

Embodiments of the invention relate to flame resistant fabrics containing fibers having at least one energy absorbing and/or reflecting additive incorporated into the fibers. Inclusion of such fibers into the fabric increases the arc rating/fabric weight ratio of the fabric while still complying with all requisite thermal protective requirements.

A woven flame-resistant fabric for garments, the warp and fill yarns being made up of at least about 30 wt. % inherently flame-resistant fibers. The fabric is woven from a plurality of warp yarn groups consecutively arranged across the width direction in a recurring pattern, each warp yarn group consisting of a plurality of adjacent consecutively arranged warp yarns. At least one warp yarn in each warp yarn group is woven with the fill yarns in a plain (1/1) weave and at least one warp yarn in each warp yarn group is woven in one or more non-plain weaves each selected from the group consisting of 1/2, 2/1, 2/2, 1/3, and 3/1. Approximately half of the warp yarns in the fabric are woven in a plain (1/1) weave and the remaining warp yarns in the fabric are woven in the one or more non-plain weaves, in an alternating fashion.

Embodiments relate generally to systems and methods for providing protection from arc flash. A material for arc flash protection may comprise a first layer of textile material configured to face an arc flash, the first layer comprising a woven or knitted fabric; and a second layer of textile material configured to face a user's skin, the second layer comprising a quilted fabric having at least one oxidized polyacrylonitrile fiber. A method of forming a material for protection from arc flash may comprise providing a first layer of textile material configured to face an arc flash, the first layer comprising a woven or knitted fabric; quilting one or more layers of material to form a second layer of textile material configured to face a user's skin, the second layer comprising at least one oxidized polyacrylonitrile fiber; and attaching the first layer to the second layer to form a completed textile.

Flame resistant fabrics having antimicrobial properties that combat odor and/or resist hazardous microorganisms. The fabrics are particularly suitable for use in clothing and more particularly in protective garments designed to be worn by individuals, such as military personnel and emergency rescue personnel, at risk of exposure to fire and extreme temperatures as well as hazardous substances. The fabrics may be formed in a variety of ways, including, but not limited to, incorporating antimicrobial fibers into the flame resistant fabric yarn or by treating the pre-formed flame resistant yarn or fabric with antimicrobial agents in a dyeing or finishing process.

A flame resistant shirt includes an outer layer that has a main body portion and a pair of sleeves. The main body portion terminates in a bottom edge. The flame resistant shirt also includes an inner curtain that is coupled to an inner surface of the main body portion and has a top edge and an opposing bottom edge. The top edge of the inner curtain is located at a waist region of the main body portion and the inner curtain extends downwardly therefrom and the bottom edge of the inner curtain is disposed above the bottom edge of the main body portion. The inner curtain is intended to be tucked into a bottom garment, while the outer layer is intended to be worn untucked.

A flame resistant shirt includes an outer layer that has a main body portion and a pair of sleeves. The main body portion terminates in a bottom edge. The flame resistant shirt also includes an inner curtain that is coupled to an inner surface of the main body portion and has a top edge and an opposing bottom edge. The top edge of the inner curtain is located at a waist region of the main body portion and the inner curtain extends downwardly therefrom and the bottom edge of the inner curtain is disposed above the bottom edge of the main body portion. The inner curtain is intended to be tucked into a bottom garment, while the outer layer is intended to be worn untucked.

Embodiments of the present invention relate to communications tarpaulins. In one embodiment, the communications tarpaulins include a textile layer, a plurality of antenna elements, and a communications hub. The communications hub includes a plurality of radio frequency (“RF”) connectors. The communications hub is affixed to the textile layer. The RF connectors are each conductively coupled to one of the antenna elements. The RF connectors each demountably receive a communications device. The antenna elements are each affixed to the textile layer and includes a conductive composition. The antenna elements each include a conductive composition. The conductive composition includes a polymer and fully exfoliated single sheets of graphene that are present as a three-dimensional percolated network within the polymer. The textile layer includes a first textile layer and a second textile layer that are coterminous and physically coupled together and thereby form a multilayered structure.