A body impact protection system includes an inner layer and an impact force dampening and defusing structure. The inner layer includes a material composition and is adjacent to a body part when the body impact protection system is worn. The impact force dampening and defusing structure is juxtaposed to the inner layer and includes a plurality of components. The components function to reduce pressure on the body part from an impact force on a layer by layer basis. Each layer of the system dampens and defuses the impact force such that, by the time it reaches the body part, it has been substantially attenuated and spread over a large area.

A shin guard includes a protective plate having a front face and a rear face. The rear face is contoured to fit around a shin of a wearer of the shin guard. Further, the shin guard includes a three dimensional image element carried on the front face. This image element projects an image outline through a sock worn over the shin guard. A sports pad is provided including an outer shell defining a pocket and a pad received and held in the pocket. A three dimensional image element is captured between said outer shell and the front face of the pad. That image element projects an image outline through the outer shell to enhance the uniform of the player wearing the sports pad.

A vibration damping material suitable for use in a wearable garment, comprising a sheet of a flexible material with a first and a second side, both comprising a plurality of protrusions arranged in a predetermined pattern, wherein the protrusions on the first and/or second side of the sheet are arranged to be equidistant from adjacent protrusions, wherein the protrusions are distributed in a substantially uniform pattern throughout the first and/or second side of the sheet of flexible material, wherein the protrusions on the first side of the sheet are arranged to be offset with respect to the protrusions on the second side of the sheet of flexible material. A wearable garment comprising such a vibration damping material is also disclosed.

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.

Disclosed herein is an integrated combination of materials within a vesicle, comprising a space filling porous or fibrous structure and an engineered nonuniform elastic truss to form an impact mitigating Hybrid Material System (HMS). The macroscale and microscale structures within the HMS can be configured to absorb kinetic energy and reduce the forces transmitted by impacts through the HMS to any surface or body in contact with the HMS.

A flexible energy absorbing system comprising a material coated, impregnated and/or combined with a strain rate sensitive substance is disclosed. It is formed so as to define repeating adjacent cells, each cell having a re-entrant geometry such that, upon impact, the material locally densifies at the impact site.

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.

The present disclosure relates to flexible energy absorbing systems and body armor, helmets and protective garments incorporating flexible energy absorbing systems. A flexible energy absorbing system may comprise a first plurality of cells having a first re-entrant geometry and a second plurality of cells having a second, different geometry. The first plurality of cells and the second plurality of cells may comprise an elastomeric material.

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 impact protection device includes a first shell configured to be disposed on a body portion of a user, a second shell spaced at a distance from the first shell, and a set of elastomeric members spanning the distance between the first shell and the second shell. Each elastomeric member includes a first end and an opposing second end, each first end comprises a first end portion disposed within a corresponding opening defined by the first shell and a terminal portion disposed against an inner wall of the first shell and each second end connected to the second shell. The set of elastomeric members are configured to stretch between the first shell and the second shell in response to a translation of the second shell relative to the first shell and at a location that is substantially opposite to an impact receiving location of the second shell.