Multi-impact multi-layer body armor is presented. A first layer is a single layer of front covering material. A second layer, is a ballistic ceramic plate formed of a plurality of curved smaller ceramic tiles that are bonded together using a structural adhesive. A third layer formed of one or a plurality of aramid layers such as Kevlar® XP. A fourth layer formed of a rigid backing plate, formed of ultra-high molecular weight polyethylene such as Spectra Shield®. A fifth layer is a single layer of rear covering material. Thus, an improved body armor is presented which is inexpensive to produce, light, durable and can sustain multiple impacts.

The invention relates to a method for manufacturing a composite sheet comprising high performance polyethylene fibres and a polymeric resin comprising the steps of assembling HPPE fibres to a sheet, applying an aqueous suspension of a polymeric resin to the HPPE fibres, partially drying the aqueous suspension, optionally applying a temperature and/or a pressure treatment to the composite sheet wherein the polymeric resin is a homopolymer or copolymer of ethylene and/or propylene. The invention further relates to composite sheets obtainable by said method and articles comprising the composite sheet such as helmets, radomes or a tarpaulins.

The invention relates to a process for making high-performance polyethylene multi-filament yarn comprising the steps of a) making a solution of ultra-high molar mass polyethylene in a solvent; b) spinning of the solution through a spinplate containing at least 5 spinholes into an air-gap to form fluid filaments, while applying a draw ratio DRfluid; c) cooling the fluid filaments to form solvent-containing gel filaments; d) removing at least partly the solvent from the filaments; and e) drawing the filaments in at least one step before, during and/or after said solvent removing, while applying a draw ratio DRsolid of at least 4, wherein in step b) each spinhole comprises a contraction zone of specific dimension and a downstream zone of diameter Dn and length Ln with Ln/Dn of from 0 to at most 25, to result in a draw ratio DRfluid=DRsp*DRag of at least 150, wherein DRsp is the draw ratio in the spinholes and DRag is the draw ratio in the air-gap, with DRsp being greater than 1 and DRag at least 1. The invention further relates to a high-performance polyethylene multifilament yarn, and to semi-finished or end-use products containing said yarn, especially to ropes and ballistic-resistant composites.

An Anti-Ballistic chair having a back portion, a seat portion, and an Anti-Ballistic panel within at least one of the back portion, and the seat portion, wherein the Anti-Ballistic portion comprises at least a first layer of Anti-Ballistic material formed from high-strength synthetic fibers extending in a first direction, and at least a second layer of Anti-Ballistic material formed from high-strength synthetic fibers extending in a second direction, different from the first direction.

The present invention relates to an armoury assembly (100) for the protection of a structural material (115) and/or load-carrying element (85) having a longitudinal axis, wherein the armouiy assembly is provided longitudinally surrounding the structural material (115) and/or load-carrying element (85) to be protected, wherein the armouiy assembly (100) comprises at least two different layers, one being an energy-absorption matrix (20), the other layer (10) being made of a metal, an alloy or a fibre reinforced polymer having a thickness less than the energy-absorption matrix (20), wherein two or more longitudinal channels (30) are being provided to the armouiy assembly (100), wherein the channels (30) are substantially parallel to the longitudinal axis of the structural material (115) and/or the load-carrying element (85).

A rigid ballistic-resistant composite includes large denier per filament (dpf) yarns. The yarns are held in place by a resin to form a rigid composite panel with improved ballistic performance. The large dpf yarns may be selected from aromatic heterocyclic co-polyamide fibers, polyester-polyarylate fibers, high modulus polypropylene (HMPP) fibers, ultra high molecular weight polyethylene (UHMWPE) fibers, poly(p-phenylene-2,6-benzobisoxazole) (PBO) fibers, poly-diimidazo pyridinylene (dihydroxy) phenylene (PIPD) fibers, carbon fibers, and polyolefin fibers.

A projectile-resistant table provides a reduced weight by employing separate structures for table stiffness and projectile resistance, for example, using a sandwich structure composite with high stiffness and tow projectile resistance for table integrity and a flexible fiber mat with low stiffness but high projectile resistance for shielding.

A projectile-resistant table provides a reduced weight by employing separate structures for table stiffness and projectile resistance, for example, using a sandwich structure composite with high stiffness and tow projectile resistance for table integrity and a flexible fiber mat with low stiffness but high projectile resistance for shielding.

An kinetic object protection system for protecting a space in a building or vehicle comprising a protective barrier including one or more sheets of a laminated material having a plurality of layers of lightweight, flexible, ballistic resistant material such as woven sheets, nets, or mesh which are secured together using a glue, heat weld, or stitching. The system may include an automated control system operably configured to cause a change in state of the barrier from a retracted state to a protective deployed state, which may include a sensing system operably configured to detect a threatening event, wherein the sensing system upon sensing the threatening event triggers the barrier to transition from the retracted state to the deployed protective state such that in the protective state, the barriers are adapted to be resistant to penetration by the kinetic objects such as vehicles.

A ballistic fiber composition may include a fabric that may be comprised of polyamide fibers, an adhesive polymer coating the fabric, and a carbonaceous material and a ceramic filler embedded in the adhesive polymer coating. A method of producing a ballistic protective article may include mixing a carbonaceous material and a ceramic filler into an adhesive to create a mixture, and then coating a polyamide fabric with the mixture. A ballistic protective article may include an aromatic polyamide fabric that is coated with an elastomeric adhesive polymer coating, with calcium carbonate and a carbonaceous material embedded in the elastomeric adhesive polymer coating. The carbonaceous material may include at least one material selected from graphene, carbon nanofiber, and carbon nanotubes.