A composite structure for stab protection includes layers of flat structures placed on top of each other, and an embedding material, wherein, in at least some of the layers placed on top of each other, the flat structures of adjacent layers are offset relative to one another, the flat structures of the composite structure are at least partially embedded in the embedding material, and the composite structure includes separated connecting elements, wherein before they are separated, the separated connecting elements have connected at least some of the flat structures of adjacent layers with one another.

The present invention discloses a shark resistant composite fabric that has an outer layer of a woven or knitted shark bite resistant fabric material; an intermediate layer neoprene; and an inner layer of a woven or knitted shark bite resistant fabric material.

Disclosed is a dipping composite material for enhancing the cut resistance of chemical-resistant gloves, wherein an additive is added to a latex, and the additive is a metal oxide and/or silica and/or glass fiber and/or basalt fiber and/or aramid fiber. The present invention improves the formula of a dipping layer such that the dipping layer has the cut resistance, which can significantly improve the cut resistant level of gloves.

A multilayer protective device such as, but not limited to, a garment such as a vest or arm or leg wrap, a bag, a backpack, wraps for tents, camping items, etc. designed to be worn by domesticated or farm animals of various sizes and/or humans or placed on objects for which predator attack is to be deterred. The multilayer protective device is made from a multi-layered composite textile containing a non-toxic, non-lethal repellent substance such that upon a bite from an attacking animal, the non-toxic, non-lethal repellent substance is released deterring the attacking animal for such a time as to allow the wearer or user of the protective device to escape or be rescued.

Provided is a reinforcement fiber for a protection product. The reinforcement fiber includes multiple adjacent filaments, each filament is composed of a core and a shell formed around the core, and a melting temperature of the shell is lower than a melting temperature of the core, the shell of each filament attached to the shell of the adjacent filament. The reinforcement fiber can be manufactured into a protection product with good impact resistance simply through heating and molding.

A protective garment comprising multi-layered composite structures is conformable to the contours of the body parts for which protection is required. The composite structure contains rigid impact-deflecting outer structures, impact-dissipating gel middle layers, and impact-damping microlattice lower layers. In one embodiment, the structure is designed for impacts associated with contact sports, such as football, hockey and lacrosse. In another embodiment, the structure is designed for military/police applications, in which impacts can be blunt forces, from weapons such as clubs, or penetrative forces, from knives, bullets or shrapnel.

A garment for watersports formed with at least one textile. The textile comprising a face fabric and a membrane. The membrane being fixed to the face fabric and wherein the textile comprises primary yarns and secondary yarns in which the secondary yarns have a higher stiffness relative to the primary yarns.

Garments made from a composite, protective fabric are disclosed. The composite fabric has textile layers placed in proximity to metallic mesh layers of woven stainless steel mesh. The metal mesh layers formed from any metal which forms suitable fibers. The textile layers are fabric formed with well-known fabric fibers selected from those including para-aramid fibers, meta-aramid fibers, ultra-high molecular weight polyethylene fibers, polyethylene terephthalate fibers, cellulose fibers, polyamide fibers, a mixture of para-aramid fibers and meta-aramid fibers, and a mixture of para-aramid fibers and carbon fibers. Forming the non-metal textile layers is by any suitable method for interlacing yarns including weaving, knitting, crocheting, knotting, or felting, or combinations thereof. The garments made using the fabric include gloves, bullet proof vests and chain-saw resistant trousers.

A spike resistant package containing a pouch, a first grouping of spike resistant textile layers, and a slip layer. Each of the textile layers within the first grouping of textile layers contains a plurality of interwoven yarns or fibers having a tenacity of about 5 or more grams per denier. At least a portion of the spike resistant textile layers comprise about 10 wt. % or less, based on the total weight of the spike resistant textile layer, of a coating comprising a plurality of particles having a diameter of about 20 m or less on at least one of the surfaces of the spike resistant textile layer. The slip layer has a stiffness of less than about 0.01 N-m and a static coefficient of friction (COF) between the slip layer and the second side of the first grouping of less than about 0.40. The pouch encapsulates the grouping of textile layers and slip layer. An article containing the package is also described.

A spike resistant package containing a pouch, a first grouping of spike resistant textile layers, and a slip layer. Each of the textile layers within the first grouping of textile layers contains a plurality of interwoven yarns or fibers having a tenacity of about 14 or more grams per denier. The slip layer has a thickness of less than about 0.1 mm, a stiffness of less than about 0.01 N-m, and a static coefficient of friction (COF) between the slip layer and the second side of the first grouping of less than about 0.40. The pouch essentially fully encapsulates the grouping of spike resistant textile layers and the slip layer and the slip layer and the inner surface of the pouch are in direct and intimate contact. An article containing the package is also described.