A moldable portion for use with protective equipment, guards, braces, or the like for use to protect from injury and facilitate healing of the same are disclosed herein. This moldable portion includes a thermoplastic semi-crystalline propylene ethylene copolymer having a crystallinity of about 2% to about 65% that is between about 85% to about 99% of the moldable portion and a microwave susceptor that is about 1% to about 15% of the moldable portion These moldable portions may be adapted to be positioned adjacent an area of an user's anatomy it is intended to protect, and may be prepared for customization by heating to a temperature of about 60° C. to about 100° C. and shaped and configured to be affixed to a portion of the protective equipment.

A method for manufacturing individualized protective gear such as pads based on a body scan, and the resulting pads, are disclosed herein. A body scan is taken of a wearer-defined area for a desired set of pads. The scan is converted to a mesh model. The mesh model is used to define a first surface of the pad shell and then translationally or orthogonally offset to provide a second surface of the pad shell. The mesh is also flattened to provide a liner for the pad. The shell may be manufactured using additive printing technology. The shell and the liner are then attached, such as by adhesive.

A soft armor panel is provided by work softening a panel formed of a ballistic material. The panel also includes slip planes between adjacent ply groups, the adjacent ply groups remaining unconnected or substantially unconnected at the slip plane. The soft, or conformable, body armor, is resistant to various projectile threats, in which the panel is made by work-softening an otherwise rigid panel. The soft armor panel includes a work softened lamination of a plurality of ply groups. Each ply group comprises one or more layers, each layer comprising a composite material of fibers embedded in a matrix material. A slip plane is disposed between at least one set of adjacent ply groups, such that the adjacent ply groups remain unconnected or substantially unconnected at the slip plane. The softened ballistic panel retains significant ballistic properties, is light weight and can be readily conformed to various torso configurations.

The present disclosure is directed to articles that include a cured coating that includes a matrix of crosslinked polymers and optionally a colorant (e.g., pigment particles or dye or both). The cured coating can include a matrix of crosslinked polymers. The cured coating is a product of crosslinking a coating composition comprising uncrosslinked polymers (e.g., a dispersion of uncrosslinked polymers in a carrier to form the matrix of crosslinked polymers), wherein the uncrosslinked polymers are crosslinked to form the matrix of crosslinked polymers. The matrix of crosslinked polymers can be elastomeric. The present disclosure is also directed to articles including these bladders, methods of forming these bladders, and methods of making articles including these bladders, where the bladders include the cured coating.

Provided herein is a device for reinforcing the lower body during the performance of a compound weightlifting exercise including at least two thigh bands, each defining an opening for a wearer's thigh, at least two biasing straps, each biasing strap having a proximal end and a distal end, each biasing strap connected at the distal end thereof to one of the at least two generally circular thigh bands, and a waist portion connected to the proximal end of each biasing strap. When worn, each of the biasing straps extends between the waist portion and the thigh bands, over one of the wearer's buttocks and a rear portion of the wearer's thigh.

A weighted wearable training apparatus has a weight shell with a front surface, a rear surface, a top, a bottom, a first side edge and a second side edge. The weight shell is adapted to cover at least a portion of a user's limb. A plurality of pockets are positioned on the rear surface of the weight shell. At least one removable weight sized to fit within one of the pockets. At least one attachment mechanism is provided for holding the weight shell to the user's limb.

Protective sports garments are provided that include integrated cut-resistant panels located adjacent to relatively vulnerable parts of a user's body. A shirt garment may include integrated cut-resistant panels around the end cuffs of each sleeve, and such integrated cut-resistant panels may help prevent cutting injuries from a hockey skate blade or other object. The location(s) of the integrated cut-resistant panels may be selected to provide additional protection that complements protection already provided by other protective equipment, such as elbow pads, arm pads, or other padding or armor that may be worn. Additionally, in some cases, described garments may provide a pad securement mechanism that may help to secure certain pads in place relative to the garment. In other examples, protective pants are provided that include one or more cut-resistant panels, such as cut-resistant panels in a lower back leg portion to provide protection to a player's Achilles tendon area.

A leg pad for a hockey goaltender comprising a pad body with an inner side and a cuff member extending rearwardly from the inner side. In use, the cuff member and a portion of the inner side define a longitudinal channel in which the calf of the goaltender is at least partially received, wherein upper and lower projections of the cuff member at least partially surround respective upper and lower parts of the calf and wherein the cuff member tightly maintains the leg within the channel while allowing movement of the leg between a standing position and a knelt position.

A bespoke protective sports helmet to be worn by a player engaged in a sporting activity is provided. The bespoke helmet includes i) systems and methods for acquiring, storing and processing a player's unique data, namely the player's anatomical features, where that player is to wear a protective sports helmet, (ii) for systems and methods of using the player's unique data to manufacture a protective sports helmet with a custom formed internal padding assembly that substantially corresponds to the player's unique data, and (iii) a protective sports helmet designed using the acquired and processed unique player's data and including the custom formed internal padding assembly that provides improved fit and comfort for the player. The system and method allows for the design and manufacture of a bespoke protective sports helmet that is purposely designed and manufactured to match the player's anatomical specifications.

The present disclosure provides a method of preparing a silver alloy composite nanomaterial. The preparation method comprises forming a silver alloy comprising at least one of copper, zinc, magnesium, aluminum and titanium into a composite metal rod; evaporating the silver alloy of the composite metal rod, resulting in a gaseous alloy; rapidly cooling the gaseous alloy so as to condense the silver alloy into a solid state; and collecting the cooled powder so as to obtain the silver alloy composite nanomaterial.