The present invention relates to a flexible ballistic armor apparatus for deflecting high velocity firearm, fragmentation, or shrapnel projectiles with a flexible armor unit. The apparatus minimizes the deterioration of the armor when subjected to shock waves or shear forces of a ballistic impact. The present invention also relates to the use of a flexible armor unit with soft body armor, a vehicle, a vessel, an aircraft or in structural applications.

A method of using an anti-ballistic protection system for protecting an interior space in a building. The ballistic barrier includes a laminated material having a plurality of layers of lightweight, flexible, ballistic resistant material such as woven sheets which are secured together into the laminate using a adhesive, heat weld, or stitching. The ballistic barrier in the deployed state is configured to be resistant to penetration by high-speed ballistic projectiles such as a bullet fired from a gun or a shrapnel from a bomb to protect the interior space, and can be used to protect windows, doors, hallways, and walls from penetration by the ballistic projectiles.

A multi-layer ballistic woven fabric, including an upper woven layer having upper warp yarns and upper weft yarns that are interwoven together to form the upper woven layer. The multi-layer ballistic woven fabric also includes a lower woven layer having lower warp yarns and lower weft yarns that are interwoven together, and a plurality of securing yarns, each securing yarn interwoven with at least some of the upper yarns and some of the lower yarns so as to secure the upper and lower woven layers together. At least one of the securing yarns is woven underneath a first lower weft yarn, then above a second upper weft yarn adjacent the first lower weft yarn, then underneath a third lower weft yarn adjacent the second upper weft yarn and then above a fourth upper weft yarn adjacent the third lower weft yarn. The multi-layer ballistic woven fabric is formed by interweaving the securing yarns with the warp yarns and weft yarns as the upper woven layer and lower woven layer are made.

A macro fiber for a composite article may include a plurality of inner fibers. Each one of the inner fibers may have an inner fiber final cross-sectional size of less than approximately 100 nanometers. The inner fibers may be surrounded by matrix material.

A hybrid core comprising a matrix and tubular structural reinforcements, such as a ductile matrix core reinforced with ductile hollow tubes, as well as panels which comprise such hybrid core. Embodiments of the invention manifest resistance to both interfacial debonding and ballistic penetration.

A method of processing ultra high hardness steel is provided to increase its usefulness in armor applications. The method involves slowly cooling the ultra high hardness steel to a cryogenic temperature, slowly returning the steel to an ambient temperature, slowly heating the steel, and again slowly returning it to an ambient temperature.

The invention is the first modification of the Patent Application with number 1009231 and involves an additional system of three levels which reinforces and improves the dynamic armor of main battle tanks using compressed ferromagnetic powder and electromagnetically reinforced. The main characteristics of the first invention (DE-1009231) for the armor system of tanks and battle vehicles was the use of compressed powder from magnetized or non-magnetized ferromagnetic pulverized materials (Fe, Ni, Co) or other similar synthetic materials that enrich or enhance the desired mechanical properties and the effect of electromagnetic amplification between two solid passive armor plates. The first level (FIG. 1, 2) concerns the placement of high temperature silicone or other material of the same mechanical properties at a suitable thickness proportional to the threat, between the outer passive solid shielding plate and the compressed ferromagnetic powder. The second level (FIG. 1, 3) concerns the modification of the layer containing the ferromagnetic powder by the distribution of the ferromagnetic powder contained in pellets or cubes or rectangular parallelepipeds or other basic geometric volumes from polymeric material with viscous elasticity or other kinds of material with same mechanical properties of thin walls or alternatively its placement in a spatial network with cubic or conical or spherical partition volumes with thin walls made of polymeric material with viscoelasticity or other material with the same mechanical properties and then compress them between the plates of solid passive armor. The third level of reinforcement (FIGS. 1, 4) was achieved by placing a layer of explosive material on the visible side facing to the ferromagnetic powder of the inner passive solid shielding plate in combination with percussion, perforation and temperature sensors. The layer of the explosive may be in a single layer or be contained as based on the inside surface of each individual area of the spatial network or similarly to separate cubes or rectangular parallelepipeds.

A ballistic material utilizes a three-dimensional, square-based pyramid unit cell (SBPUC) sphere structure that includes four base spheres and a primary sphere, which are tightly packed and in contact with each other. The base spheres and the primary sphere are arranged whereby the centers of each of the base spheres form corners of a square base, while the center of the primary sphere forms an apex, which when connected to the corners, forms an imaginary pyramid. The ballistic material is formed from one or more layers of SBPUCs that are provided between a pair of spaced substrate layers, so as to achieve the desired level of ballistic protection performance.

Resin compositions, layers, and interlayers comprising two or more poly(vinyl acetal) resins and at least one blending agent or haze reducing agent are provided. Such compositions, layers, and interlayers exhibit enhanced optical properties while retaining other properties, such as impact resistance and acoustic performance.

A bulletproof panel includes: (i) a ceramic plate A; (ii) at least one phenol resin impregnated aramid fabric laminate C having phenol resin impregnated aramid fabrics C1, C2 and C3 which are laminated thereon; and (iii) an epoxy resin impregnated fabric B disposed between the ceramic plate A and the phenol resin impregnated aramid fabric laminate C, and impregnated with an epoxy resin. The phenol resin impregnated aramid fabrics C1, C2 and C3 may be aramid fabrics impregnated with a phenol resin, and aramid fabrics impregnated with a phenol/polyvinyl butyral mixture resin. The ceramic plate A and the phenol resin impregnated aramid fabric laminate C are not delaminated from each other even under a high-temperature environment, and thereby greatly enhancing the bulletproof performance.