A welder's garment assembly for protecting a welder from heat and electricity includes a garment that can be worn by a user. The garment is comprised of a pair of insulating layers that are sandwiched between a pair of covering layers. Each of the insulating layers is comprised of an energy absorbing material to protect the user during welding. A respective one of the covering layers is comprised of a resilient material to protect the insulating layers from abrasion. Furthermore, a respective one of the covering layers is comprised of a deformable material for enhancing comfort for wearing the garment.

A multi-layered material with low thickness is provided, having properties of thermal and electric insulation, flame retardant capacity and high mechanical strength, useful for the manufacture of personal protective equipment and more in general of work items for the protection against arc flash effects. The material provides a high grade of protection against arc flash with good flexibility and comfort for the wearer, who is thus protected without being hindered in movements.

Protective combat clothing (PCC) may include a shirt and trousers, wherein the shirt and the trousers are at least partially made of woven fabric made of a composition of the materials comprising flame-resistant fiber, flame-resistant meta-aramid fiber, heat-resistant fiber, polyimide and anti-static fiber.

An arc resistant acrylic fiber includes an acrylic polymer. The arc resistant acrylic fiber also includes an infrared absorber in an amount of 1 wt % to 30 wt % with respect to a total weight of the acrylic polymer.

Systems, methods and articles having a heat-shielding or blocking, heat-dissipating and/or heat signature-reducing material layer or coating are disclosed. In one example, the heat-shielding or blocking, heat-dissipating and/or heat signature-reducing material completely covers the interior of a housing having a plurality of battery cells removably disposed therein. Other examples include a heat-shielding or blocking, heat-dissipating and/or heat signature-reducing material layer having anti-static, anti-radio frequency (RF), anti-electromagnetic interference (EMI), anti-tarnish, and/or anti-corrosion materials and properties that effectively protect battery-operated devices and/or the batteries that power them from damage or diminished operation.

Relatively lightweight laminate structures having an outer textile layer, a heat reactive material, a middle layer, a flame retardant adhesive material and an inner layer, wherein the flame retardant adhesive material is positioned in a pattern so as to form a plurality of pockets, each of the pockets defined by (a) the middle layer, (b) the inner layer, and (c) a portion of the flame retardant adhesive material. The laminate structures can provide protection from an exposure to an electrical arc.

The electrostatics shield for attracting, capturing and binding expelled electrostatics charged aerosols in the air. The eShield guarding and shielding facial coverings and orifices and gaps between said facial coverings and faces to prevent the transmissions of respiratory diseases.

A reusable protective clothing, including parameters of: (1) anti-permeability water pressure being: hydrostatic pressure of a new protective clothing ≥1100 cm H.sub.2O, and hydrostatic pressure after 100 times of repeated use ≥40 cm H.sub.2O; (2) moisture permeability of a material used ≥2500 g/(m.sup.2.Math.d), moisture permeability after 20 times of repeated use ≥5000 g/(m.sup.2.Math.d), and moisture permeability after 100 times of repeated use ≥8000 g/(m.sup.2.Math.d); (3) synthetic blood penetration resistance ≥grade 2 in table 3 of GB19082-2009; (4) outer surface water spray grade ≥grade 3; (5) breaking strength ≥45 N; (6) elongation at break ≥15%; (7) filtration efficiency for non-oily particles ≥70%; (8) charge amount ≤0.6 μC/piece; (9) static decay time ≤0.5 second; (10) continuous burning time ≤15 seconds, smoldering time ≤10 seconds, damage length less than 20 mm.

An electrical system comprising conductive and insulating layers for application to a surface of a garment, the electrical system comprising: a first insulating layer for attaching to a garment; a second insulating layer; and an electrically conductive layer encapsulated between the first insulating layer and the second insulating layer. The first and second insulating layers have a predetermined minimum voltage withstand and a predetermined minimum resistance.

An electromagnetic camouflage shield comprises a flexible conductive layer and a textile layer. The shield includes at least one outward facing fibrous face, and is creped with at least 5% increased elongation to enhance its flexibility and effective EM thickness. The conductive layer can be the textile layer, or a separate layer. In embodiments, the conductive layer is one of a woven that incorporates metallic yarns, a textile having an electroless plated metal coating, a metal mesh, a thin layer of foil, and an elastomeric layer having a conductive and/or ferrite filler. The textile layer can be a woven or non-woven. Embodiments are fashioned into shirts, pants, and/or other clothing, and can provide drape and moisture vapor transport for enhanced comfort.