Abstract: Provided herein methods and structures for construction of light weight sandwich panels or load-bearing panels having improved ballistic protection. The methods disclosed can facilitate construction of a hybrid core comprising ballistic fabrics and deformable pins that exhibit superior resistance to ballistic penetration. The methods and structures of the present disclosures can be advantageously used in many applications, such as armored vehicles.

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: In accordance with a particular embodiment of the present disclosure, a method to mitigate a blast wave includes detecting an imminent explosion that produces a blast wave. In response to this detection, the energy of a portion of this blast wave may be reduced by deploying a fluid in the path of the blast wave.

Abstract: A blast mitigating seat features a base and a seat frame. The seat frame includes a pan and a backrest including an open area for gear worn by a user. A first damping subsystem between the base and the seat frame has a first force/stroke relationship and a second damping subsystem between the base and the seat frame has a second force/stroke relationship.

Abstract: A device and a method for protecting objects against rocket-propelled grenades having a hollow nose cone includes a netting of knotted and coated superstrong fibers disposed in front of the object, in such a manner that the nose cone of a rocket caught in the netting will penetrate one of the meshes of the netting and be deformed through strangulation, thereby disabling the detonator.

Abstract: A web includes strings and connectors that form ogive damagers. An ogive damager has three or more strings and three or more connectors. The connectors connect the strings to form a closed loop having an area that allows at least a tip of an ogive of a rocket to pass through the area. Each ogive damager is configured to damage the rest of the rocket.

Abstract: A ballistic armor shield assembly attached to a Stryker armored vehicle comprises a three-sided armor shield assembly with transparent armor, which is bolted around a driver hatch directly onto the military armored vehicle using existing bolts and holes. The armor shield assembly comprises a front, left and right side armor frames forming the 3-sided assembly to which transparent armor (ballistic glass) sections are attached and secured. An enclosure is provided on the left side of the armored shield assembly for attaching and removing the entire left side transparent armor in order to facilitate vehicle engine maintenance. The driver is provided with full armor protection while operating the vehicle with his body extending out of the open hatch for improved vision. When the hatch is partially closed, the driver has full protection on the front, left, and right from the armor shield assembly as well as above from the hatch.

Abstract: An armor plate is provided for use in the ballistic protection of a structure against projectiles incoming from an expected threat direction. The armor plate comprises a layer of pellets made of ballistic material; a gap having a contour at least partially defined by circumferential surfaces of those of the pellets that are exposed to the gap, and occupying an area corresponding to a plurality of the pellets; and an insert inserted within the gap and having an outer surface at least a part of which has an outer shape mimicking the contour of the gap. There is also provided a method for producing the armor plate and an insert for use therein.

Abstract: A kit for fitting a vehicle with protective armor includes an armored floor panel configured to be installed to a frame of the vehicle below an occupant compartment of the vehicle, and an armored shell configured to be received over an outer body of a cab of the vehicle. The armored shell may be removed to return the vehicle to its original, non-armored condition.

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 single crystal sapphire. The composite may provide adequate protection from projectiles while exhibiting large surface areas and relatively low areal densities.

Abstract: This invention relates to an armour arrangement (10). The armour arrangement (10) comprises a plurality of disruption members (12) located adjacent one another, being at least partially spaced apart from one another and being angularly displaced relative to the surface. Each disruption member is arcuate in cross-section and includes three disruption bodies (14), positioned side-by-side to, such that the disruption member is in the shape of a half-parabolic curve.

Abstract: Lightweight, ballistic resistant articles are provided. More particularly, armor structures incorporating two or more spaced apart, ballistic resistant panels, having superior impact and ballistic performance at a light weight. The panels are spaced by air or by an intermediate material.

Abstract: Process for producing fabrics comprising at least one layer of unidirectionally arranged polymeric tapes with the tapes comprising at least a core component, the process comprises the steps of forming at least one layer of unidirectionally arranged polymeric tapes in a weaving machine with the polymeric tapes being used as warp yarn and a binding thread being used as weft yarn or with the polymeric tapes being used as weft yarn and a binding thread being used as warp yarn and subsequently consolidating the at least one monolayer using pressure and heat, characterised in that the melting temperature of the binding yarns lies below the consolidating temperature and the melting temperature of the core component of the polymeric tapes lies above the consolidating temperature.

Abstract: A method of applying, through spray on, extruded or flow-on application, a projectile resistant material. The method includes selecting an epoxy, selecting a fiber, selecting a ratio for combining the epoxy and the fiber, based on the ratio, combining the epoxy and the fiber to form a malleable projectile resistant type material, and applying the material. The projectile resistant material includes an epoxy and several fibers. The fibers are mixed within the epoxy based on a predetermined ratio. The predetermined ratio is for determining the projectile resistance of the material. The fibers are randomly disposed within the epoxy.

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 protective device for use in containing high energy debris and pressure is provided which employs a plurality of energy absorption elements disposed on an outer surface of an inner sheet, where the outer surface faces away from the body being protected and toward the high energy event, such as an explosion. Each energy absorption element extends generally away from the body to permit the high energy event to first impact upon the energy absorption elements, rather than the body. Energy absorbing elements are configured with a base and a cap and are formed of laminate composite materials. As such, energy absorption elements are configured to contain or reduce high energy debris material and pressure impacting the energy absorption element through delamination and possibly penetration of the composite material.

Abstract: A composite armor 10 is provided with a cellular structure 12 having a plurality of composite inserts 14 arranged in openings 20 provided in the cellular structure 12. A pair of laminate sheets are arranged on oppositely facing sides of the cellular structure 12 and covering the inserts 14. The laminate sheets 26 and 28 are bonded to the structure 12 and the inserts 14 by an adhesive. The cellular structure 12 includes a plurality of fibers extending continuously throughout the cellular structure 12.

Abstract: A ballistic and blast protective composite panel includes a first composite layer and a second composite layer.

Abstract: A composite armor panel and a method for making the armor is disclosed. In one embodiment the armor consists of a plurality of ceramic tiles (21) individually edge-wrapped (52) with fiber or edge-wrap fabric, which are further wrapped with a face-wrap fabric, and encapsulated in a hyperelastic polymer material (31) permeating the fabric and fibers, with a back plate (41) adhered to the encapsulated tiles. In one embodiment the hyperelastic polymer (31) is formed from a MDI-polyester or polyether prepolymer, at lease one long-chain polyester polyol comprising ethylene/butylene adipate diol, at least one short-chain diol comprising 1,4-butanediol, and a tin-based catalyst.

Abstract: A ballistic weapon stand has a base plate for mounting armor panels having front and rear faces. The armor panels are fastened to and extend upwardly from the base at an angle in the range of 10-30° with respect to the vertical to define a protected space behind the panels. Struts are welded to the base plate and extend upwardly toward and through an opening in a middle armor panel and between the edges of the middle armor panel and side armor panels. Welding plates are constructed and arranged for welding to the struts on the rear faces of the armor plates. The welding plates extend over the rear faces of the armor plates at junctions between the armor plates. A weapon platform is disposed on a second portion of at least one of the struts for mounting a weapon in the protected space to fire out past the front face of the armor panels. A transparent projectile defeating shield is mounted to swivel with the weapon, preferably on the weapons stand.

Abstract: The present invention is directed to structures, constructions and assemblies able and functional to protect living subjects from a range and variety of moving objects differing in size, volume, and overall shape; from projectiles traveling at many different rates of speed, and from the effects of exploding and/or advancing solid fragments moving at high velocity. More specifically, the present invention relates to protecting living human and animal subjects through the use of three-dimensional designed structures and assemblies which employ configured and dimensioned penetration-resistant plates prepared from laminated constructs comprising multiple individual layers composed of asymmetric composite materials. These penetration-resistant plates will protect living subjects from high velocity projectiles and fragments in both civilian and combat situations.

Abstract: An armored cab for a vehicle is provided, the cab including multiple layers of armoring material, and having a shape to assist in the deflection of radar and the various types of ordinance which may be fired or exploded against the armored cab.