Abstract: A steel armour comprising between 90% and 50% bainite, the rest being austenite, in which excess carbon remains within the bainitic ferrite at a concentration beyond that consistent with equilibrium; there is also partial partitioning of carbon into the residual austenite. In one embodiment of the invention the bainite comprises in weight percent: carbon 0.6 to 1.1%, silicon 1.5 to 2.0%, manganese 0.5 to 1.8%, nickel up to 3%, chromium 1.0 to 1.5%, molybdenum 0.2 to 0.5%, vanadium 0.1 to 0.2%, balance iron save for incidental impurities. In particular it was noted that excellent properties were obtained if the manganese content is about 1% by weight. By forming the steel as a pearlite sheet the elements (310,410) of the panel can be formed easily by cutting or stamping before final transformation to bainite. Cutting may also occur after final transformation using water- jet or laser cutting. Alternatively hot forging elements is described.

Abstract: An apparatus for providing protection from blast and ballistic energy is provided. The apparatus includes a liquid storage mechanism containing a liquid and a rigid layer internal to the liquid storage mechanism. The apparatus also includes a pressure release mechanism configured to allow the liquid to exit the liquid storage mechanism when a pressure sufficient to open or activate the pressure release mechanism contacts the liquid storage mechanism and presses the liquid storage mechanism against the rigid layer.

Abstract: The invention relates to an air hardenable high-hardness steel for armouring applications, such as armour plate for use in light armoured vehicles and body armour, and having a high level of ballistic performance relative to its plate thickness. In particular, the invention concerns a high ballistic strength martensitic armour steel which, in an air cooled and untempered condition, has a strength coefficient (s0) of higher than 2500 MPa; a flow parameter (P) of higher than 8.0, preferably higher than 18.0; and a manganese content of 1.8 to 3.6% by weight of manganese, preferably 2.8 to 3.1% by weight of manganese. The armour steel also includes retained austenite at a volume fraction of at least 1%, and preferably a volume fraction of 4 to 20%.

Abstract: A rigid structure for ballistic protections is described. The structure comprises a plurality of textile elements which are distinct from each other and co-operate with each other to stop an incident bullet along a direction. A third element is placed between two of the textile elements. Such third element is aimed at creating a discontinuity surface between the two adjacent elements, which provides a further reduction of the trauma value and increase of the stopping capability.

Abstract: An armor includes a core that, in turn, includes a first layer of prismatic elements arranged in a tessellated fashion and a second layer of prismatic elements arranged in a tessellated fashion. The first layer of prismatic elements is nested into the second layer of prismatic elements. An armor includes a strike face sheet, a rear face sheet, and a core disposed between the strike face sheet and the rear face sheet. The core includes a first layer of prismatic elements arranged in a tessellated fashion, a second layer of prismatic elements arranged in a tessellated fashion, and a strain isolation layer. The first layer of prismatic elements is nested into the second layer of prismatic elements with the strain isolation layer disposed between the first layer of prismatic elements and the second layer of prismatic elements.

Abstract: A ballistic shield for protection against up to 7.62×63 mm AP rounds (NIJ Level IV). The ballistic shield is multiple layered and includes polymer foam, ceramic tiles, and a support structure fabricated from ballistic resistant fabric. Individual layers are bonded with adhesives and preferably wrapped with fabric. Under the fabric cover of the exterior surface of the shield is a polymer foam layer that exhibits excellent blast impact resistance and blast attenuation properties as well as a hard ceramic or the like layer. The foam layer is preferably made from liquid crystal or semi-crystalline polymer to enhance fire resistance and provide enhanced ductility. According to various preferred embodiments, the man-portable ballistic shield also incorporates a compact video system for viewing the front side of the ballistic shield to eliminate the transparent view port of current ballistic shields and protective foam about the periphery and on the rear surface thereof.

Abstract: An assembly for armoring an amphibious vehicle against projectile penetrations, the amphibious vehicle having a hull, the assembly including a rigid spall generating sheet, the rigid spall generating sheet having a thickness and an outer surface; a buoyant sheet fixedly attached to and extending inwardly from the rigid spall generating sheet; and a multiplicity of fasteners interconnecting the rigid and buoyant sheets with the amphibious vehicle's hull, the buoyant sheet incorporating a low density, nonabsorbent hardened foam material; the buoyant sheet functioning for vehicle buoyancy enhancement and for defining a spall dispersal space overlying the hull and underlying the rigid spall generating sheet.

Abstract: An armor system includes a hard face and at least one reinforcing layer covering a rear surface of the hard face. The reinforcing layer is fabricated from a glass-ceramic material exhibiting crystalline bodies throughout the mass of the glass-ceramic material. At least one resilient layer forms a rearward outer layer of the armor system. The hard face and cooperating reinforcing layers serve to disburse energy caused by the impact of an incoming projectile with the armor system, while the resilient layer serves to retain any pieces of the hard face and reinforcing layers fractured during ballistic impact. In certain embodiments, a plurality of hard faces, each with cooperating reinforcing and resilient layers, are held in parallel and spaced apart arrangement.

Abstract: An armor system for defeating a solid projectile has an outer armor plate, an interior armor plate, and an inner armor plate, the plates positioned approximately parallel to one another and also displaced from one another along the projectile trajectory to form a first dispersion space between the outer armor plate and the interior armor plate, and a second dispersion space between the interior armor plate and the inner armor plate. The first and second dispersion spaces are each sufficiently thick to allow significant lateral dispersion of any armor fragments passing therethrough.

Abstract: An armor uses optimally shaped ceramic cross-pellets and a matrix for containing the cross-pellets. The armor comprises front and back plates and an array of interlocking ceramic cross-pellets of repeating shape between front and back plates. Each cross-pellet may have a horizontal cross-section in the shape of a cross and comprises a center and four fingers projecting therefrom. Each cross-pellet in a non-peripheral portion of the array may be supported by fingers of other cross-pellets which may include two fingers from each of four other cross-pellets. The result is lightweight, composite hybrid structure. The dense, hard armor has good fracture toughness, hardness and a high capacity to absorb impacts for ballistic protection particularly suited to tactical ground vehicles. Valley spaced is minimized. A polymer resin may be situated in spaces between the ceramic cross-pellets and between the array and at least one of the back plate and front plate.

Abstract: An armor and a system for projectile neutralization. The armor has at least one serrated plate or louvered plate system. The serrated plate has a base, recessed lands, raised lands, and columnar projections extending from the recessed lands to the raised lands to form serrations on the serrated plate. The louvered plate system has a series of angled plates, a base, a top and a support structure connecting the louvered plates with the base and the top. The system has a serrated or louvered armor plate configured to reduce a kinetic energy of the projectile and re-orient the projectile upon rupture through the armor plate, and has a projectile-receptor configured to capture the projectile after rupture through the armor plate. Projectiles which impact on the serrated or louvered plate system have a kinetic energy thereof reduced and become re-oriented upon rupture through the serrated or louvered plate system.

Abstract: An armor system for defeating a solid projectile having a first armor plate, an interior armor plate, and an inner armor plate displaced from one another to form a first dispersion space between the first armor plate and the interior armor plate. The first dispersion space is sufficiently thick to allow significant lateral dispersion of armor passing therethrough. The inner armor plate is disposed approximately parallel to the interior armor plate and displaced therefrom to form a second dispersion space between the interior armor plate and the inner armor plate. The second dispersion space is sufficiently thick to allow significant lateral dispersion of materials passing therethrough.

Abstract: Prefabricated ribbed ferrocement element E sandwich type is effused in the mould K with vibrating motor 14 embedded, and it consist from box looking shell 15 made from ferrocement with fortified ribs 16 thermal isolation layer 17 and protective layer 5; on the side of the elements E hooks 18 have been positioned made from armature and used for removing elements from the mould K and his placement on the construction site. Moustaches 19 made from armature and positioned on the frontal side of the element serve for binding with armature of the reinforced concrete arches 6; they have an optional openings 8 made for windows, ventilation and other installations. A construction structure is constructed using the prefabricated ribbed ferrocement element E.

Abstract: In an embodiment, a monolithic tile made for use in a composite armor is disclosed. The tile includes cut-out and/or through thickness channels spaced from each other at a distance greater than a dimension of the channels, in a plan view of the tile.

Abstract: A multilayer backing composite for armor plate systems. One embodiment provides a ceramic layer and a bonded multilayer backing layer bonded to the ceramic layer. The backing layer can be formed from at least two layers each of alternating elastomeric interstitial layers and UHMWPE layers having an areal density in the range of about 125 to 400 g/m2. The areal density of the stack can be in the range of about 4 to 15 lbs/ft2, and specifically about 6.98 lbs/ft2. In some embodiments, at least one of the at least two UHMWPE layers nearer to the ceramic layer of the stack can have a lower areal density than at least one layer further from the ceramic layer. The ceramic layer can be SiC and 0.280? thick; each rubber layer can be about 0.01?; and each UHMWPE layer can be about 0.15?.

Abstract: An example armor system includes a first ceramic matrix composite armor layer, a second ceramic matrix composite armor layer, and a monolithic ceramic armor layer directly bonded to the first and the second ceramic matrix composite armor layers.

Abstract: An integrally formed high density ceramic pellet, for use in a ballistic armor plate, has a longitudinally extending body portion and an impact receiving end face. The impact receiving end face includes an impact receiving proximal segment that is convexly curved and a distal segment that merges with a top surface of the body portion. The distal segment has lateral surfaces that have a region including at least a portion which is concave in configuration or a region including a substantially smooth angled configuration. A cross-sectional area of the distal segment at the area of merger is greater than a cross-sectional area taken across a nominally designated base of the proximal segment. The length of the contour line of the outer surface of the distal segment is between 5 and 25% of that of the entire integrally formed impact receiving end face.

Abstract: A bullet-resistant armour element for use as a tessellation in a flexible armour matrix has a hard main body and a facing over said main body, such as layer of polymeric or polymer matrix composite material, wherein the facing has an acoustic impedance which is substantially lower than the acoustic impedance of the main body. Groups aid elements tessellate to form an aperture between the adjacent elements, and a cover element is arranged to cover said aperture. Limit stops restrict the degree of articulation between the adjacent elements. The elements include a deflector for deflecting bullet splash and traps for collecting bullet splash.

Abstract: Protective armor panels comprising a polymer layer having upper and lower faces generally forming a sheet and a plurality of metal strips each having an upper edge, a lower edge and side faces, said side faces being oriented generally traverse to the upper face of said polymer layer and positioned at least partially within the polymer layer, are disclosed.

Abstract: A class of lightweight ballistic protection material and methods of forming such materials are disclosed. The material comprises a composite of polymeric material comprising high modulus resins and ceramic materials. The composite materials offer the advantage of being relatively easy to fabricate and lower in cost than competing materials. Body armor, blast protection panels and other articles comprising the new ballistic protection materials are also disclosed.

Abstract: A reactive armor that may include multiple layers. The reactive armor may include a self-healing outer layer, a ceramic tile layer and a backing layer. The ceramic tile layer may include a plurality of ceramic tiles and explosive material. The ceramic tiles may be hexagonal. The ceramic tiles may each define a hollow space in which the explosive material is deposited. The reactive armor may be combined with non-reactive armor.

Abstract: An armor panel having an impact face is provided. The armor panel includes at least one rigid absorbing layer and a high-tensile confining layer surrounding the at least one rigid absorbing layer. The at least one rigid absorbing layer can have a plurality of strip-shaped protection elements that are adhered to one another along a plane substantially orthogonal to the impact face. The at least one rigid absorbing layer can be formed of a glass-ceramic material having a coefficient of thermal expansion substantially equal to zero and that, upon impact by a projectile, converts to a dilatant power at least in an area of impact.

Abstract: An armor system for defeating a solid projectile having an exterior rigid armor plate associated with a fiber-reinforced sheet armor affixed to the interior surface of the exterior armor plate, an interior armor plate, and an inner armor plate displaced from one another to form a first dispersion space between the sheet of self-bonded polymer and the interior armor plate. The first dispersion space is sufficiently thick to allow significant lateral dispersion of armor passing therethrough. The inner armor plate is disposed approximately parallel to the interior armor plate and displaced therefrom to form a second dispersion space between the interior armor plate and the inner armor plate. The second dispersion space is sufficiently thick to allow significant lateral dispersion of materials passing therethrough.

Abstract: The present invention's stratified composite material system of armor, as typically embodied, comprises a strike stratum and a backing stratum. The strike stratum includes elastomeric matrix material and inventive ceramic-inclusive elements embedded therein and arranged (e.g., in one or more rows and one or more columns) along a geometric plane corresponding to the front (initial strike) surface of the strike stratum. More rigid than the strike stratum, the backing stratum is constituted by, e.g., metallic (metal or metal alloy) material or fiber-reinforced polymeric matrix material. Some inventive embodiments also comprise a spall-containment stratum fronting the strike stratum. The inventive ceramic-inclusive elements geometrically describe any of various inventive modes, including: first mode, having a flat front face and a textured back face; second mode, having a pyramidal front section and a prismatoidal (especially, prismoidal, e.g.

Abstract: An exemplary embodiment provides transparent reactive armor systems that are far lighter than conventional reactive armor systems due to the materials used therein. The reactive armor of embodiments of the present invention is composed of at least three layers. These layers are—from the outside to the inside—the front plate, the explosives layer and the explosives substrate as well as optional further inside layers with antiballistic effects. Consequently, the explosives substrate can be part of a multilayer laminate.

Abstract: A reactive armor that may include multiple layers. The reactive armor may include a self-healing outer layer, a ceramic tile layer and a backing layer. The ceramic tile layer may include a plurality of ceramic tiles and explosive material. The ceramic tiles may be hexagonal. The ceramic tiles may each define a hollow space in which the explosive material is deposited. The reactive armor may be combined with non-reactive armor.

Abstract: A ceramic composite and method of making are provided. The ceramic composite may be transparent and may serve as transparent armor. The ceramic portion of the composite may be spinel. The composite may provide adequate protection from projectiles while exhibiting large surface areas and relatively low areal densities.

Abstract: A contained volume of particulate materials that is optimized for eroding ballistic penetrator, explosively formed penetrators, shaped charges, ballistic fragments, and other ballistic threats. The particulate materials include crushed garnet, crushed ceramics and sand. The volume of particulate materials may be mixed with explosive rods or pills. These explosive rods or pills ignite when the ballistic threat reaches a preset area within the armor box. Particulate material and armor boxes can consist of configurations using ballistic balls and irregular shaped stones or gravel. Alternate embodiments may contain configurations utilizing ballistic rods, electronic timing devices, and explosive detonators.

Abstract: A ceramic ballistic material and method of manufacture is disclosed. A filler material is provided. The filler material is divided into filler granules collectively having a median diameter approximately 10 microns or less. An amount of carbon is provided. The carbon is divided into carbon particles and the carbon particles are allowed to coat the filler granules. The mixture of carbon-coated filler granules is formed into a ballistic armor shape. The formed mixture is placed in a substantial vacuum. The mixture is introduced to a pre-selected amount of silicon and the mixture of carbon-coated filler granules and silicon is heated to a temperature at or above the melting point of the silicon.

Abstract: Methods and systems for an armor system are provided. The system includes a first face sheet and a shaped preform extending from the first face sheet. The preform includes a first edge proximate the first face sheet, a sidewall extending from the first edge to a flange extending substantially perpendicularly from the sidewall. The preform circumscribes an area of the first face sheet. The system also includes a tile of armor material complementarily-shaped to fit within the area circumscribed by the preform. The tile is positioned within the preform such that at least a portion of the tile is between the first face sheet and the flange. The system includes a second face sheet covering the preform and the tile on a side opposite from the first face sheet.

Abstract: An armor including a first panel having a first surface and a second surface and a second panel having a first surface facing the second surface of the first panel and a second surface. Wherein at least a portion of at least one of the first surface of the first panel and the second surface of the first panel is on a first plane that intersects a second plane defined by at least a portion of at least one of the first surface of the second panel and the second surface of the second panel.

Abstract: In one embodiment, a protective armor system includes first and second armor layers separated by a gap. The second armor layer has a hardness that is less the first armor layer. The protective shield is configured to disperse energy of a shaped charge, such as the energy within a penetrator generated by an explosively formed penetrator (EFP).

Abstract: A contained volume of particulate materials that is optimized for eroding ballistic penetrator, explosively formed penetrators, shaped charges, ballistic fragments, and other ballistic threats. The particulate materials include crushed garnet, crushed ceramics and sand. The volume of particulate materials may be mixed with explosive rods or pills. These explosive rods or pills ignite when the ballistic threat reaches a preset area within the armor box. Particulate material and armor boxes can consist of configurations using ballistic balls and irregular shaped stones or gravel. Alternate embodiments may contain configurations utilizing ballistic rods, electronic timing devices, and explosive detonators.

Abstract: An armor system for defeating a solid projectile having a first armor plate, an interior armor plate, and an inner armor plate displaced from one another to form a first dispersion space between the first armor plate and the interior armor plate. The first dispersion space is sufficiently thick to allow significant lateral dispersion of armor passing therethrough. The inner armor plate is disposed approximately parallel to the interior armor plate and displaced therefrom to form a second dispersion space between the interior armor plate and the inner armor plate. The second dispersion space is sufficiently thick to allow significant lateral dispersion of materials passing therethrough.

Abstract: An assembly useful for constructing concealable, flexible, lightweight protective body armor includes a flexible support layer to which is bonded a mosaic of rigid, adjacent tiles having a high bending performance, such as type 5 titanium alloy, which includes 6% aluminum and 4% vanadium by weight. The inner support layer can include woven para-aramid and/or STF-treated Kevlar™. The tiles can have interlocking and/or thickened edges. An additional backing layer can include para-aramid and/or carbon nanofiber embedded UHMWPE UD-laminate. An inner layer can have high moisture transport, anti-microbial properties, and low friction. An outer layer can be shaped with anatomical features to hide the armor. The assembly can be flame resistant. Assemblies with 2 mm thick tiles and total thickness less than 5 mm can provide V50 protection against 9 mm FMJ projectiles at more than 1000 feet/second, and can also protect against knife and spike assaults at 65 Joules force.

Abstract: An apparatus for providing protection from ballistic rounds, projectiles, fragments and explosives. The apparatus includes a core, grinding layer and bonding layer. The core is shaped and configured as a structural truss of the apparatus, in which the core includes a plurality of parallel, adjacent rows and the core distributes and dissipates force impacting on the apparatus. The grinding layer is positioned on at least one side of the core facing towards potential threats, in which the grinding layer grinds rounds, projectiles, fragments or other materials impacting the apparatus, helping to dissipate the impacting material and its momentum. The bonding layer bonds the grinding layer together and the grinding layer to the core and provides an outer coating to the apparatus on a side of the apparatus facing potential threats and through which rounds, projectiles, fragments or other materials impact and penetrate the apparatus.

Abstract: Structures based upon periodic cellular materials that provide a potential for defeating combinations of both air blast loading and ballistic attack either sequentially or simultaneously, or combination of both. The cellular structures may also be configured to meet the stiffness and strength support requirements of particular vehicle or other applications, systems or structures. The armor is therefore potentially able to support normal service loads and defeat blast and ballistic threats when necessary. The structure provides for using efficient load support capabilities of the material (without a high armor protection level) in low threat conditions, as well as the ability to modify the system to increase its level protection to a desired or required level. This would reduce the weight of the protection system in normal (low threat) conditions which reduces vehicle wear and tear, as well as cost savings in fabrication of applicable structures or systems.

Abstract: Methods and apparatus for ballistic shielding and protective armor; and more particularly, representative and exemplary embodiments of the present invention generally relate to improved methods and systems for ballistic deflection and protection through dynamic armor and/or the like.

Abstract: The invention relates to a composite armor comprising multiple isolated reactive charges in various shapes and in various configurations. Charges are reacted and dynamically pressurize ceramic elements to reinforce the armor and to disrupt the projectile penetration process. In one embodiment of the present invention an armor comprising a multitude of high tensile strength enclosures are arranged in a closely packed pattern. A ceramic element is disposed in each individual enclosure; a thin inter-layer of explosive material is disposed between the ceramic element and the enclosure's strike face. In a ballistic event, the explosive is set off by an incoming projectile and the ceramic element is thus pressurized and reinforced.

Abstract: A method and apparatus for defeating high-velocity projectiles. A plurality of disks of equal size comprised of fiber induced ceramic composites are provided. The disks are laid out in an imbricated pattern row by row such that each disk in a row is in substantially a straight line with the other disks in the row and overlaps a segment of a disk in an adjacent row. The imbricated pattern is then adhered to a flexible, high tensile strength substrate and overlaid by a second high tensile strength layer such that the imbricated pattern is enveloped between the substrate and the second layer. The envelope is then coupled to a soft body armor backing.

Abstract: A compact bullet-proof shield capable of providing full-body protection consisting an upper part, the upper part consisting of a bullet-proof viewing area surrounded by a bullet-proof fabric set in a hardening resin, and a lower part consisting of a second bullet proof fabric attached to the lower side of the upper part of the invention, which second bullet proof fabric is folded up, and which fabric can become unfurled when the user of the present invention needs full body protection from a bullet fired from gun which is in front of the user.

Abstract: One or more embodiments contained herein disclose a structural insulated panel having improved ballistics properties and methods for using the same.

Abstract: A semi-fabricated armor layer for use in production of an armor panel adapted to protect a body from an incoming projectile comprises a carrier and a plurality of armor elements. Each armor element has front and rear end surfaces and a side surface extending therebetween along a height axis of the element. The carrier is flexible and each of a majority of the armor elements is bonded to the carrier at one of its end surfaces and is free of bonding to adjacent armor elements at its side surface. When the carrier has a planar orientation, at least a majority of the armor elements has their height axes essentially parallel to each other and, when the carrier is at least slightly bent, the height axis of at least one of the elements is inclined relative to the height axis of another of the armor elements adjacent thereto.

Abstract: The present invention is directed to an armor system that protects vehicle occupants from lands mines or improvised explosive devices. In the preferred embodiment, the armor system has an arc member, a membrane, reactive blocks, and a reactive block enclosure. The armor system is designed to dissipate, neutralize, and redirect explosion energy, fragments and shrapnel, thereby ensuring the safety of the vehicle occupants.

Abstract: A ceramic amour plate (1,41,50,70) having auxetic reinforcement (2,40,51,71). The auxetic reinforcement may be provided utilising auxetic fibres, auxetic knits or weaves, or lay-ups exhibiting auxetic behaviour. The auxetic reinforcement reduces cracking of the ceramic plate to improve multi-hit performance. The reinforcement may be provided as a layer (2,40, 51) bonded to the surface of the ceramic plate (1,41,50) or as an integral part (71) of the ceramic plate (70).

Abstract: Composite materials in various shapes and sizes and in various configurations for use in ballistic armor confined in cylindrical and dome shaped enclosures; held under pressure to increase the impact absorption factor. An armor comprising an auxiliary layer disposed in front thereof at a determined distance wherein said layer comprises pre-stressed members arranged in a spacious pattern. A method is proposed for manufacturing of pre-stressed structure and armor by expanding the cavity into which ceramic materials are inserted so that pressure is applied to the ceramic materials.

Abstract: A composite armor panels is comprised of a first layer, composed of a matrix of an elastomeric material and a crushed aggregate material, and a second backing layer. One or more geogrids can be included in the first layer of the armor panel to prevent the aggregate material from moving within the first layer. A method of making a composite armor panel includes exposing a mixture of elastomeric material and crushed aggregate material to elevated temperatures and pressures for predetermined time periods, such that a matrix of elastomeric material and crushed aggregate material is formed.

Abstract: A portable protection system including a selectively collapsible truss for supporting a protection member. The truss is movable between a collapsed position and an expanded position. The protection member includes at least one layer of ballistic armor material for disrupting a projectile. The truss includes suitable connectors for releasably connecting the protection member to the truss, and also suitable connectors for releasably connecting the truss to an adjoining truss so as to form a protection wall.

Abstract: A roll-up curtain comprised of ballistic plates bonded onto flexible material is described. Strips of ballistic steel or rigid ballistic composite are bonded onto high-tensile strength flexible material, allowing the device to roll-up, as a curtain, while maintaining the same ballistic benefits of the components when unrolled.

Abstract: A method for making armor plate that is resistant to armor piercing small arms ammunition is provided. The armor plate includes a steel plate having a nominal chemical composition in weight percent of 0.4C-1.8Ni-0.8Cr-0.25Mo. The steel plate is carburized on one side and produces a carburized side and a non-carburized side. The carburized side of the steel plate has a carbon concentration of at least 0.9% by weight and the non-carburized side has a carbon concentration of between 0.38 and 0.45% by weight. After the steel plate has been carburized, it is subsequently thermally processed such that the carburized side has a hardness of at least 58 Rockwell Hardness C (HRC), and the non-carburized side has a hardness of between >=50 and <=55 HRC.