An impact absorbing pad includes a first layer and a second layer. The first layer has a first body-facing surface configured to be positioned adjacent a garment and a first outer surface opposite the first body-facing surface. The first layer comprises a first foam having a first density. The first layer defines a first plurality of voids that extend through the first layer at a first plurality of positions. The second layer has a second body-facing surface positioned adjacent the first outer surface of the first layer and a second outer surface opposite the second body-facing surface. The second layer comprises a second foam having a second density that is different than the first density. The second layer defines a second plurality of voids that extend through the second layer at a second plurality of positions. Portions of the first outer surface of the first layer are visible through the second plurality of voids of the second layer.

An oblique-impact protection technology member (20) contains a layer (50) of closed cell foam containing a first surface (52), a second surface (54), and a plurality of wells (56) on the first surface (52). The first surface (52) contains a plurality of first surface apertures (58) and the first surface apertures (58) have a square shape. The second surface (54) is opposite the first surface (52) and optionally contains a plurality of second surface apertures (62). Each well (56) corresponds to a first surface aperture (58) and the second surface (54) is substantially parallel; or parallel, to the first surface (52). A helmet (10) and/or a piece of sporting equipment (12) may contain this technology, and a process may manufacture this technology.

Wearable item comprising a motion control system and a method of manufacturing thereof. The wearable item comprises a body-close wearable item which, when worn by a user, at least a part of the wearable item is positioned adjacent to the body of the user. The motion control system comprises at least one layer of strain-rate sensitive material configured to control motion of one or more body parts of the user.

A pad may be worn to prevent abrasion or provide a fulcrum during exercise. The pad has a tapering thickness profile to provide support and leverage to the wearer. The pad may have an adhesive side for adhering either to a garment or directly to a wearer. Also disclosed is a variety of garments including pockets in which the pad may be removably retained.

An additively manufactured lattice includes a plurality of symmetrically oriented repeating unit cells. Each of the unit cells is comprised of a vertically oriented tubular structure having a top edge and bottom edge, said tubular structure defined by a circumferential side wall extending from said top edge to said bottom edge. The side wall has a lower portion, an intermediate portion, and an upper portion, with the lower portion terminating at the bottom edge, the upper portion terminating at the top edge, and the intermediate portion positioned between the lower portion and the upper portion. A plurality of spaced legs is included with each unit cell, with each leg formed as an outfolding of the side wall, each outfolding beginning at the side wall intermediate portion and extending progressively further outward through the side wall lower portion to the bottom edge.

A forearm and shin glider for motorcycle cornering including a deformable base with slits that allow secure and comfortable fit to the rider's arm or leg. An abrasion resistant casing is attached to the base. This casing holds a set of abrasion resistant balls made of high speed smooth abrasion resistant ceramic. The abrasion resistant balls are located by bearings, also manufactured of ceramic. This device allows the rider to make contact with the ground for support during tight cornering maneuvers with substantially reduced and minimized friction. The abrasion resistant balls move smoothly within the bearings and casing and roll when contacting the ground, creating minimal friction but also providing substantial rider support. The glider device includes air ducts for air flow to reduce friction related heat. The glider device is attached to the rider's clothing using Velcro or hook and loop attachment devices.

A layered protective structure for protective garments and equipment is disclosed. The layered protective structure comprises three layers. The first layer is the outermost layer, and it is the most rigid of the layers and has first layer holes that have at their edges rim structures extending inward into the protective structure. The second layer is an elastic net-like structure that is configured to fit at least partly between the rim structures. The first layer and the second layer are on top of the third layer, which is the innermost of the layers (i.e., towards the user when the protective structure is in use). The third layer is made of a softer and more flexible material than the first layer. The second layer spreads the impact forces and conveys at least part of them to the third layer.

A headband is provided which has a fabric layer defining pockets, padding layers positioned circumferentially around the headband in the pockets, and an impact panel. The impact panel is positioned to be proximate to the forehead of a wearer of the headband. One of the padding layers is positioned behind the impact panel, such that the padding layer is positioned between the impact panel and the forehead of a wearer.

Body-protector (1,1′) comprising: a wearable article (2,2′); a shock-absorbing pad (3) anchored to the wearable article (2,2′); wherein the shock-absorbing pad (3) comprises a first member (4) configured to absorb shock energy by an irreversible plastic deformation and a second member (5) configured to absorb shock energy by a reversible elastic deformation and wherein the first member (4) is embedded in the second member (5); wherein the first member (4) comprises a plurality of cells (6) interconnected each other via their sidewalls (7) to form a pliable sheet (8) configured to absorb energy through irreversible deformation of said sidewalls (7) or said interconnections in response to a compressive load applied to said sheet (8). Said wearable article (2) being a glove (2′) wherein said shock-absorbing pad (3) is anchored to a back of the glove (2′).

The present disclosure relates to a leg sleeve, which includes a sleeve body; a cover, connected with the sleeve body to cooperatively form a receiving portion, the receiving portion defines an opening and is configured to receive a protection member; and an anti-slip element, connected with the sleeve body or the cover, to prevent the protection member slipping out from the receiving portion. The present disclosure further provides a leg protection assembly applying the leg sleeve.