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 carry harness system includes a support belt arranged to encircle a user's waist; a shoulder harness arranged to lay over the user's shoulders on opposite sides of the user's head; two front belt support straps arranged to be on a front side of the user and extending between the shoulder harness and the support belt; two rear belt support straps arranged to be on a rear side of the user and extending between the shoulder harness and the support belt; two post receivers supported on the support belt on the rear side; and two posts. The posts are arranged spaced-apart on the rear side, fit into the receivers and extending vertically between the post receivers and a vertical elevation above the shoulder harness. The two posts are fixed to the shoulder harness and have strap connections at tops of the posts. Two object support straps extend between the strap connections forwardly and obliquely to attachments on a rear side of the object to be carried.

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.

A tactical torso tool carrier and networked control and communication system is disclosed, wherein a tactical torso tool carrier device includes a main unit configured to be worn on the torso of a person, the main unit including a housing having a docking station configured to securely attach a removable tool module, wherein the tactical torso tool carrier device facilitates communications between personnel and systems operably associated with the tactical toro tool carrier and networked control and communication system.

A load carrying and force distributing device to be worn on a user's limb is described. The device has one or more support members and a plurality of elongated compression members that couple with each of the support members at locations that are circumferentially spaced around the user's limb. The space between the plurality of compression members provides a relief area. The load carrying and force distributing device compresses the soft tissue of the limb against the bone structure to thereby reduce motion of the bone structure towards a wall of the load carrying and force distributing device when worn on the limb. A method of fitting a load carrying and force distributing device to a limb is also described. The method includes coupling the elongated compression members to each of the support members and adjusting compression to thereby reduce motion of the bone towards a wall of the device.

The present invention relates to a strap component and strap component system. The strap component has a first strap component piece and a second component piece. Each strap component piece has one or more teeth, each teeth having a base with a base width, a tip with a tip width, two side surfaces extending from the tip to the base, and a hole extending through both side surfaces. The first strap component piece and second strap component piece may be arranged whereby the one or more teeth of the first strap component piece and the one or more teeth of the second strap component piece are vertically staggered. In this arrangement, the holes of all of the teeth may be aligned whereby a connecting member may be configured through the holes to connect the first strap component piece and the second strap component piece.

A load carrying and force distributing interface to be worn on a user's limb is described. The interface has one or more support members sized and dimensioned to fit around the user's limb, at least three elongated compression members circumferentially spaced apart and around the limb, and a sensor, an actuator, and a controller configured to dynamically adjust a compression level of at least one of the elongated compression members. The controller could also be configured to adjust one or more elongated compression members so as to compress the soft tissue of the limb against the bone structure to thereby reduce relative motion between the bone structure and the interface.

A ballistic armored component attaches to the existing retention straps of common combat helmets and provides protection to the otherwise exposed lower skull and upper neck region. A fabric covering contains a soft armor or hard armor insert, and is mounted by straps or other fasteners to existing straps found in conventional helmets. The armor component may be fabric of aramid fibers, or fabric of ultra high molecular weight polyethylene fibers, or may be fabricated of a rigid plate of ceramic, polymer, or metal. The armored component adds additional protection from ground-level or subterranean munitions, by placing a ballistic shape on the lower skull region (occipital region), providing significant additional ballistic coverage with minimal weight and bulk. The fabric shell may also be connected directly to the helmet shell, to allow the component to withdraw within the helmet when the wearer's neck is flexed rearwardly.

Energy distribution structures provide architectural flexibility in various configurations, materials, and scalability, which enables a vast number of applications. An energy distribution structure or array thereof may include a three-dimensional outer component and a three-dimensional inner component within the outer component. The outer component absorbs and redirects initial energy from an applied energy event, and the inner component absorbs and redirects residual energy from the applied energy event. Such an applied energy event may be caused by a ballistic or non-ballistic impact, an instantaneous or prolonged impact such as atmospheric pressure or decompression, explosive overpressure (shockwave), low-velocity contact, and blunt force trauma. Energy distribution structures can increase the strength, resilience or survivability of such events, and reduce the injury or damage to target objects such as people, vehicles, structures, vessels and surfaces by shielding same from such events.