Abstract: The present invention relates to fabrics, composites, prepregs, laminates, and other products incorporating glass fibers formed from glass compositions. The glass fibers, in some embodiments, are incorporated into composites that can be adapted for use in high energy impact applications such as ballistic or blast resistance applications. Glass fibers formed from some embodiments of the glass compositions can have certain desirable properties that can include, for example, desirable electrical properties (e.g. low Dk) or desirable mechanical properties (e.g., specific strength).

Abstract: A structure or vehicle protection method including a removable frame on the structure or vehicle, and a net within the frame and spaced from the structure or vehicle and having a mesh size designed to disarm an incoming threat.

Abstract: A lightweight armor system may comprise multiple reinforcement materials layered within a single metal matrix casting. These reinforcement materials may comprise ceramics, metals, or other composites with microstructures that may be porous, dense, fibrous or particulate. Various geometries of flat plates, and combinations of reinforcement materials may be utilized. These reinforcement materials are infiltrated with liquid metal, the liquid metal solidifies within the material layers of open porosity forming a dense hermetic metal matrix composite armor in the desired product shape geometry. The metal infiltration process allows for metal to penetrate throughout the overall structure extending from one layer to the next, thereby binding the layers together and integrating the structure.

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: 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 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: 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 window blast shield for mounting to a window frame including a top retaining body, a bottom retaining body, a safety drapery having a strength to retard debris propelled by blast forces, the safety drapery operatively coupled with the top retaining body and the bottom retaining body, at least one safety cord disposed within a channel within at least one of the top retaining body and the bottom retaining body, wherein applying blast forces to the window blast shield the at least one of the top retaining body and the bottom retaining body fails and the at least one safety cord does not fail, and wherein the at least one safety cord supports the safety drapery allowing the safety drapery to billow and retard debris propelled by blast forces.

Abstract: An improved ceramic armor system comprising a ceramic component and a diamond powder based slurry bonded to a strike surface of the ceramic component, the diamond powder based slurry including a diamond powder and a base selected from the group consisting of a silicate and a phosphate base.

Abstract: A resource is protected by an armor structure comprising a magnetic field such that the magnetic field will interfere with a warhead blast to weaken the blast. In particular, magnetic field will interfere with a molten metal jet from a shaped charge to disperse the jet, allowing subsequent layers of armor to absorb the jet energy without penetration. In one embodiment, the magnetic field is produced by a layer of magnetic material magnetized with the field lines perpendicular to the primary threat direction and typically parallel to the surface of the area to be protected. The magnetic material layer may include ferromagnetic (iron or steel, or other) layers to strengthen and contain the magnetic field, protect the magnetic material and act as additional armor layers. The magnetic layer is typically used in conjunction with an inner shield armor layer to absorb the diffused jet after passing through the magnetic layer.

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 sheet of ballistic-resistant fiber strands includes a bi-directional array of bonding fibers interwoven with the ballistic-resistant fibers to form a fiber panel. In one embodiment, a sheet of laminated ballistic-resistant fibers is joined to the first sheet of laminated ballistic-resistant fibers with the ballistic-resistant fibers running in a second direction as compared to the first fibers. In yet another embodiment, individual laminated sheets of ballistic-resistant fibers are stitched together to form packets of sheets that may be used singularly or bundled together.

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: A sheet of ballistic-resistant fiber strands includes a bi-directional array of bonding fibers interwoven with the ballistic-resistant fibers to form a fiber panel. In one embodiment, a sheet of laminated ballistic-resistant fibers is joined to the first sheet of laminated ballistic-resistant fibers with the ballistic-resistant fibers running in a second direction as compared to the first fibers. In yet another embodiment, individual laminated sheets of ballistic-resistant fibers are stitched together to form packets of sheets that may be used singularly or bundled together.

Abstract: A composite useful in a ballistic resistant armor article comprises a first nonwoven layer comprising a first plurality of yarns the yarns comprising a first plurality of para-aramid filaments, the first plurality of yarns arranged parallel with each other and a second nonwoven layer comprising a second plurality of yarns comprising a second plurality of para-aramid filaments, the second plurality of yarns arranged parallel with each other. The first plurality of yarns of the first layer have an orientation in a direction that is different from the orientation of the second plurality of yarns in the second layer. The yarns have an elongation at break of 3.6 to 5.0 percent. The composite further comprises a thermoset or thermoplastic binding resin in the region of the interface between the two layers and a viscoelastic resin coating at least portions of external surfaces of the first and second pluralities of yarns.

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: A net deployment system which, in one example, includes a manifold assembly including multiple weight ducts and a bladder port. A weight is disposed in each weight duct and each weight is tied to the net. A bladder is behind the net and is over the bladder port. At least one inflator charge is associated with the manifold for inflating the bladder and firing the weights out of the weight ducts to deploy the net in the path of an incoming threat.

Abstract: An ordinance, such as a rocket propelled grenade, shield includes a net with hard points at select nodes of the net and cable guides on the side of the net. Cables under tension extend through the cable guides supporting the net typically in conjunction with a top cross bar, spaced top struts, and spaced bottom struts. This framis design facilitates entering and exiting the vehicle or structure.

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: A multi-layer composite armor component that includes a plurality of layers of energy-dispersion objects including a first layer that includes a first plurality of energy-dispersion objects, wherein the first plurality of energy-dispersion objects in the first layer are held in place relative to one another in a closely-packed configuration; and a first layer of bonding material, wherein the first layer of bonding material has a first durometer value, and wherein the first plurality of energy-dispersion objects are held in place relative to one another via the first layer of bonding material. A method that includes providing a plurality of layers of energy-dispersion objects; arranging the first plurality of layers of energy-dispersion objects such that each of the first plurality of energy-dispersion objects are held in place relative to one another in a closely-packed configuration; and embedding the first plurality of energy-dispersion objects in a first layer of bonding material.

Abstract: An armored cab having at least an upper wall, two side walls, a front wall, a back wall, and a bottom wall. The armored cab and its respective walls include a longitudinal axis extending from the back wall to the front wall. The bottom wall includes at least one concave surface. The at least one concave surface faces downwardly and away from the armored cab, and is disposed in a direction substantially parallel with the longitudinal axis of the armored cab.

Abstract: Textile armour (2) comprising at least one textile section (4) and corresponding supporting means (6), wherein the arrangement is such that the or each textile section is fully extended.

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 method for the manufacture of metallically encapsulated ceramic armor through the use of low pressure processing methods in autoclave furnaces or brazing furnaces.

Abstract: According to the present invention there is provided an armor array for protecting a body to be protected from an incoming projectile having an anticipated impact direction. The armor array is constituted by at least a first and a second armor cassette, each comprising a top base plate and a bottom base plate sandwiching therebetween an expandable layer. The first and second armor cassettes are spaced apart by an intermediate depressible panel having a top and a bottom face, such that the bottom base plate of the first armor cassette faces the top face of the intermediate depressible panel and the top base plate of the second cassette faces the bottom face of the intermediate depressible panel. The armor array is constructed such that upon expansion of the expandable layer, caused by the impact of the incoming projectile, at least one of the bottom base plate of the first armor cassette and the top base plate of the second armor cassette is urged towards the intermediate depressible panel and depresses it.

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 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 improved ceramic tile armor has a core of boron nitride and a polymer matrix composite (PMC) facing of carbon fibers fused directly to the impact face of the tile. A polyethylene fiber composite backing and spall cover are preferred. The carbon fiber layers are cured directly onto the tile, not adhered using a separate adhesive so that they are integral with the tile, not a separate layer.

Abstract: An armor system and method for the interior of a structure to be protected wherein releasable fastener material is secured to an inside wall of the structure and at least a first armor panel includes, in one example, a spacer layer, a ceramic hard face layer behind the spacer layer, a ballistic material behind the ceramic energy absorber layer, an encapsulant about the spacer layer, the ceramic energy absorber layer, and the ballistic material. Releasable fastener material is on the encapsulant adjacent the spacer layer for mating the panel to the inside wall of the structure.

Abstract: A method for the manufacture through diffusion bonding of metallically encapsulated ceramic armor providing enhanced ballistic efficiency and physical durability.

Abstract: The disclosed vehicle armor includes a first layer forming an interior bottom surface of the cabin and comprised of a high-strength metal material, a second layer forming an exterior bottom surface of the cabin and comprised of a high-strength metal material, and, a middle layer sandwiched between the first and second layers and comprised of a polymer material. The underbelly device is configured having a plurality of high areas and low areas creating deflection faces and separation distances between an interior of the cabin and an exterior threat. A second, multi-layer composite structure, forming an interior floor of the cabin, may be incorporated as a fragmentation penetration barrier.

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: 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: 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: In accordance with an embodiment of the present disclosure, a protective armor system may include a first armor layer. The protective armor system may also include a plate that is detachably coupled to the first armor layer. The protective armor system may also have a second armor layer that is separated from the plate by a gap. When the plate is struck by a projectile, it may be operable to increase the surface area of the tip of the projectile as the projectile accelerates the plate through the gap.

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 improvement in an electric armor system designed to prevent, among other things, a rocket-propelled grenade (RPG) from penetrating the hull of a fighting vehicle. The system includes a self-clearing electrode that will make the system less vulnerable to non-plasma objects that might otherwise short out the active armor electrodes. It optionally further allows for the early initiation of current flow at the point of penetration making it even easier to defeat incoming threats by allowing more time to break-up an incoming plasma jet.

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: In accordance with an embodiment of the present disclosure, a protective armor system may include a first armor layer. The protective armor system may also include a plate that is detachably coupled to the first armor layer. The protective armor system may also have a second armor layer that is separated from the plate by a gap. When the plate is struck by a projectile, it may be operable to increase the surface area of the tip of the projectile as the projectile accelerates the plate through the gap.

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: A method and apparatus for defeating high-velocity projectiles. A plurality tile are retained 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: An improvement in an electric armor system designed to prevent, among other things, a rocket-propelled grenade (RPG) from penetrating the hull of a fighting vehicle. The system includes a self-clearing electrode that will make the system less vulnerable to non-plasma objects that might otherwise short out the active armor electrodes. It optionally further allows for the early initiation of current flow at the point of penetration making it even easier to defeat incoming threats by allowing more time to break-up an incoming plasma jet.

Abstract: A method and device for protecting a surface. The device includes modular spaced armor assemblies having a ceramic face plate, a composite backing plate, and a lightweight low-density module therebetween. The modular spaced armor assemblies may be tiled to form a protective arrangement for protecting a desired surface. The lightweight low-density module includes one or more gas filled cavities.

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: 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: A composite armor element for protection against projectiles. At least one layer of effective bodies is disposed in rows next to one another in the composite armor element, the effective bodies being embedded in a matrix material. The effective bodies of one row are fixedly interconnected at least partially by means of webs to form a chain which is a monolithic element. An effective body element for insertion in a composite armor element comprises at least two effective bodies fixedly interconnected by at least one web to form a chain. The effective body element is a monolithic element, and a plurality of effective body elements are embedded in a matrix material.

Abstract: A hard armor composite includes a rigid facing and a ballistic fabric backing. The fabric backing is carried by the facing, and includes an array of bundled high-performance fibers. The fibers have a tensile strength greater than 7 grams per denier and a denier per filament ratio of less than 5.4.

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: Overpressure absorbing material is positioned on the exterior of an enclosure. When an explosion occurs adjacent the enclosure, the overpressure absorbing material absorbs a large portion of an incoming overpressure wave from the explosion. The overpressure absorbing material cushions the impact of the overpressure wave against the enclosure and may prevent the incoming overpressure wave from penetrating the enclosure in sufficient magnitude to cause injury to the enclosure's occupants. The overpressure absorbing material may also be positioned on the interior of the enclosure. The overpressure wave from the explosion may enter the enclosure via a breach or other opening and may resonate within the enclosure, causing injury to the enclosure's occupants. The interior overpressure absorbing material also prevents a significant magnitude of the overpressure wave from being reflected off the interior walls of the enclosure, resonating within the enclosure, and causing injury to the enclosure's occupants.