In exemplary embodiments, a device for protection of a military vehicle against repercussions from a distance-active protection system includes a protective shield pivotally attached to the vehicle that absorbs and/or redirects repercussions (e.g., shockwaves) from the distance-active protection system. A method for protecting a vehicle against repercussions of a distance-active protection system with a protection device. In other embodiments, the distance-active protection system is incorporated into a military vehicle.

In exemplary embodiments, a device for protection of a military vehicle against repercussions from a distance-active protection system includes a protective shield pivotally attached to the vehicle that absorbs and/or redirects repercussions (e.g., shockwaves) from the distance-active protection system. A method for protecting a vehicle against repercussions of a distance-active protection system with a protection device. In other embodiments, the distance-active protection system is incorporated into a military vehicle.

A ballistic-resistant barrier assembly including an elongated barrier having a vertical portion including a substantially horizontal elongated top edge, and a ballistic-resistant device having a first ballistic-resistant panel including an elongated top edge, and an engagement portion affixed to the elongated top edge of the first ballistic-resistant panel, wherein the engagement portion of the ballistic-resistant device is disposed adjacent the elongated top edge of the barrier so that the first ballistic-resistant panel is disposed in a vertical orientation adjacent the vertical portion of the barrier.

A ballistic-resistant barrier assembly including an elongated barrier having a vertical portion including a substantially horizontal elongated top edge, and a ballistic-resistant device having a first ballistic-resistant panel including an elongated top edge, and an engagement portion affixed to the elongated top edge of the first ballistic-resistant panel, wherein the engagement portion of the ballistic-resistant device is disposed adjacent the elongated top edge of the barrier so that the first ballistic-resistant panel is disposed in a vertical orientation adjacent the vertical portion of the barrier.

An outboard engine ballistic protection system is provided that can be adapted for use with existing small water craft outboard motors. A mounting band circumscribes and is affixed to the power head cowling. The mounting band may be formed of a pair of symmetrically affixed band straps that may be impinged about the cowling and secured fore and aft via a fastening mechanism. Laterally extended struts are provided offset from the port, starboard and aft sections of the power head. A panel support is perpendicularly affixed at an outer terminus of each strut. Mounted to the panel supports about an outer perimeter are a port protection panel, a starboard protection panel, and an aft protection panel. Each protection panel forms ballistic barrier system providing low weight, high energy absorbing structures and materials for ballistic protection against projectiles from munitions and/or shrapnel.

A composite comprised of: (i) at least one inverse freezing material, and (ii) an additive in the form of at least one solid particle. Articles made of the composites, and uses of the composites or the articles incorporating same, particularly for reducing incoming shockwaves, are also disclosed.

A composite comprised of: (i) at least one inverse freezing material, and (ii) an additive in the form of at least one solid particle. Articles made of the composites, and uses of the composites or the articles incorporating same, particularly for reducing incoming shockwaves, are also disclosed.

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 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 porous metamaterial is disclosed, comprising a matrix (101) having a plurality of voids (103) therein, wherein a content of interest (104) is trapped within each of at least part of the voids (103), detached from the matrix (101), thereby providing a respective unit-cell (100) of the metamaterial, with an intended predetermined property associated with the presence of the content of interest (104) within the at least one void (103). A variety of applications of the disclosed metamaterials are presented, including armors having either non-Newtonian fluids or magnetic particles confined within the voids as a content of interest. Upon subjecting the magnetic particles to a rotating magnetic field, the magnetic particles spin within the voids and gain angular momentum, thereby improving the resistance of the armor against penetration. Systems and methods for manufacturing porous metamaterial units having contents of interest confined within voids therein, are also disclosed.