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.

A chin-bar for a helmet with a crumple zone and an integrated air-flow system formed from passages running internally from the bottom to the top of the chin-bar. A scoop at the bottom of the chin-bar controls air flow. Diffusers at the top provide de-misting and fresh air to the rider.

The invention relates to a multi-step method with a number of processes and sub-processes that interact to allow for the selection, design and/or manufacture of a protective sports helmet for a specific player, or a recreational sports helmet for a specific person wearing the helmet. Once the desired protective sports helmet or recreational sports helmet is selected, information is collected from the individual player or wearer regarding the shape of his/her head and information about the impacts he/she has received while participating in the sport or activity. The collected information is processed to develop a bespoke energy attenuation assembly for use in the protective helmet. The energy attenuation assembly includes at least one energy attenuation member with a unique structural makeup and/or chemical composition. The energy attenuation assembly is purposely engineered to improve comfort and fit, as well as how the helmet responds when an impact or series of impacts are received by the helmet.

A method for fitting a pre-existing standard helmet to the head of a user, the helmet includes an optronic device intended to be positioned in front of the eyes of the user, the method comprising: A) measuring the dimensions of the user's head, the dimensions of the head comprising a volume of the head and a position of the eyes, B) obtaining the dimensions of the helmet, the dimensions of the helmet including a volume of the helmet, C) defining a lining for the helmet so as to ensure the positioning of the optronic device in front of the user's eyes, the lining having a top face that is intended to be applied against an inner face of the helmet and a bottom face that is intended to be applied against the user's head, the lining having a flexible cellular structure, the manufacture of the lining being adapted to the dimensions of the head and to the dimensions of the helmet, D) manufacturing the lining as defined in step C), and E) placing the lining inside the helmet.

A device for reducing impact forces upon a surface includes a base comprising a first contact portion and a transition portion, a contact member disposed between the base and the surface; and a biasing portion disposed between the first contact portion of the base and the surface. At least a first portion of an impact force upon the surface is transferred from the contact member to the base, and a second portion of the impact force is subsequently returned to the surface, the second portion being less than the first portion.

A helmet for protecting a head of a wearer, such as a hockey, lacrosse, football or other sports player. The helmet includes an outer shell and an inner padding disposed between the outer shell and the wearer's head when the helmet is worn. The inner padding includes a plurality of shock absorbers and an interconnector interconnecting the shock absorbers, each shock absorber being deformable in response to a rotational impact on the helmet such that an outer part of the shock absorber moves relative to an inner part of the shock absorber in a direction tangential to an angular movement of the outer shell due to the rotational impact.

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.

Disclosed are methods, devices, and systems for improved protective clothing such as helmets and protective headgear, including improvements in modular, semi-custom or customized helmet liners and/or inserts to enhance wearer comfort and reduce the deleterious effects of impacts between the wearer and other players and/or objects in all types of wearer activities (i.e., sports, military, equestrian, etc.).

A body part protector includes an inner layer defining an interior space that is configured to be occupied by a human body part, an outer layer connected to the inner layer and forming at least one chamber therebetween, and a plurality of separate dampers. A damper is at least partially disposed in the chamber. Each damper extends into the interior space along a respective longitudinal axis. Each damper has an outer end disposed at a fixed position relative to the outer layer and an inner end disposed longitudinally opposite the outer end in the interior space. The protector includes a plurality of separate engagement members corresponding to the plurality of dampers. Each engagement member is disposed at the inner end of the corresponding damper and is configured to engage the body part of the user. Each damper includes a plurality of compressible damper elements concentrically arranged about the longitudinal axis.

An impact resistance spreading helmet is disclosed. The helmet includes a frontal section configured to interface with the forehead of an individual and extend upward over the cranium; a medial section for extending over a portion of the cranium rearward of the frontal section; an occipital section for extending rearward from the medial section and configured to cover a portion of the neck of the individual; a first compressible structure disposed between the frontal section and the medial section; and a second compressible structure disposed between the medial section and the occipital section. The interface between the frontal section and the first compressible structure is disposed at an angle vertical to a force direction perpendicular to the frontal section above the forehead of the individual.