Padding materials capable of use as or incorporation into protective products, and methods of producing such padding materials. The padding material includes a base and an array of raised unit cells that individually protrude from a surface of the base so that the unit cells are spaced apart from each other. The base and the unit cells are formed of a cured polymeric material that contains fine porosity, and a substrate formed of a textile or fabric material is embedded in the base and permeated by the cured polymeric material.

The present disclosure relates to a protective garment, impact absorbing pads for use in a protective garment and methods of producing a protective garment. Certain embodiments of the present disclosure provide a protective garment comprising at least two impact absorbing pads, the at least two impact absorbing pads being arranged laterally across the garment with a lateral space between the at least two pads.

Embodiments of the present invention relate to a protective pad that is comprised of an impact shell and a damping component. The damping component may be formed by a plurality of connecting members that are separated from the impact shell by a plurality of extension members that extend between the damping lattice and the impact shell. The damping component may also be formed by a sheet-like form that is separated from the impact shell by a plurality of extension members that extend between the damping sheet and the impact shell. The damping component is formed from an elastomer that aids in absorbing a portion of an impact force that is distributed across the damping component by the impact shell. The dampening component may be affixed to the impact shell by way of a coupling frame that is incorporated into the impact shell.

A protective glove having a unitary dorsal panel formed from an inner scrim material and a plurality of protective elements molded directly to an exterior surface of the inner scrim. The plurality of protective elements are formed in an array of discrete islands each separated by zero-elevation interstitial spaces. The unitary dorsal panel is sewn or otherwise attached circumferentially to the palmer sections of the glove. This array provides increased protection to the user's fingers, hands, wrists, and lower forearms while maintaining flexibility and tactile feel on both palmar and dorsal sides of the glove, increasing flexibility where needed without compromising protection.

A crash protection module for mounting on wearable armour, the crash protection module including a mounting base adapted to receive an external device, an energy absorbing element on the mounting base, the energy absorbing element configured to compress generally along a longitudinal axis on impact, wherein the energy absorbing element is adapted to be received in a cooperating recess of wearable armour. Wearable armour such as a helmet containing the crash protection module is also disclosed.

An interdigitated cellular cushioning system includes an array of void cells protruding from each of two sheet layers interdigitated between the two sheet layers. Peaks of each of the void cells are attached to the opposite sheet layer forming the interdigitated cellular cushioning system. The interdigitated cellular cushioning system may be used to absorb and distribute a source of kinetic energy incident on the interdigitated cellular cushioning system (e.g., an impact or explosion) so that the amount of force transmitted through the interdigitated cellular cushioning system is low enough that it does not cause injury to personnel or damage to personnel and/or equipment adjacent the interdigitated cellular cushioning system.

A disclosed method for manufacturing a glove includes forming a base via molding, the base being shaped to include a palm portion and one or more extremity portions. The method also includes forming a top skin via molding, the top skin including one or more compartments, and forming a backhand assembly by attaching one or more edges of the one or more compartments of the top skin to the base. At least one remaining edge of each of the one or more compartments is unattached from the base. The method also includes reversing an orientation of the backhand assembly, filling each of the one or more compartments of the top skin with foam, and attaching the at least one remaining edge of each of the one or more compartments to the base.

Implementation described and claimed herein include a cushioning structure and method for manufacturing a cellular cushioning system, which allows for maximum comfort through the compression and shock cycle. Specifically, a cushioning structure comprises void cells formed in an array, which comprise multiple outwardly curved surfaces, with varying radius measurements. Stiffness in the void cells can vary by varying the Radii. Outwardly curved surfaces prevent buckling and provide support for high impact by absorbing energy.

Aspects herein are directed to an article of apparel having a vent opening formed by overlapping the edges of a first panel and a second panel. A plurality of discrete overlay film structures are applied to the second panel adjacent to the vent opening. When the article of apparel is exposed to an external stimulus, the film structures undergo a reversible increase in dimension in at least the z-direction which cause the second panel of material to undergo a reversible decrease in dimension in the direction of a longitudinal axis of the vent opening thereby causing the vent opening to dynamically transition from a closed state to an open state.

An article that includes a vortex-generator device may include various features. For example, the article may include a material layer and one or more elongate members coupled to the material layer. In addition, the one or more elongate members interconnect two or more vortex generators.