A helmet can include an upper body comprising an interior surface comprising a locking flange, and a lower body positioned at least partially inside the upper body. The lower body can comprise an edge in contact with the locking flange of the upper body. At least one joining pin can be located within, and bridge, the lower body and the upper body. An at least one basket pair can comprise an upper basket comprising a pin receiver, the upper basket being at least partially embedded within the upper body. A lower basket can comprise a pin aperture, the lower basket being at least partially embedded within the lower body and positioned such that the pin aperture is aligned with the pin receiver of the basket pair. The at least one joining pin can be positioned inside both the pin aperture and the pin receiver of the basket pair.

A football helmet with shell, faceguard, padding and comfort liner system, has replaceable nose bumpers for connecting a top center of the faceguard to the shell, button and keyhole connectors connecting the liner to an inner surface of the padding and T-nut connectors for connecting the padding to an inner surface of the shell. Front portions of the comfort liner have harder foam cushions than other portions of the liner to improve impact absorption. Selected areas of the padding system contain pads with inner and outer molded thermoplastic urethane parts of different durometer, each including a sheet with plural alternating hollow protrusions. The faceguard has an upper bar with raised ends above a lower edge of the front portion of the shell that form a face opening and on either side of the nose bumper.

A helmet can comprise an upper-body and a lower-body nested within the upper-body. An opening can be formed within a front portion of the helmet and disposed between an outer surface of the upper-body and an inner surface of the lower-body. A first magnet can be encased within the upper-body or the lower-body and adjacent the opening. A shield can comprise a shield mount and a second magnet coupled to the shield mount that is sized to fit within the opening and to be releasably coupled to the first magnet. The first magnet and the second magnet can be self-aligned in direct alignment with eyes of a user. A third magnet can be disposed above the first magnet and aligned with the second magnet on an outer surface of the helmet out of sight from eyes of the user.

The protective sports helmet disclosed herein including a crown energy attenuation assembly positioned within a crown region of the helmet shell and includes: a first energy attenuation element with a plurality of sidewalls arranged to form a hexagonal housing, wherein a first sidewall has a substantially planar configuration; a second energy attenuation element with a plurality of sidewalls arranged to form a hexagonal housing, wherein a first sidewall has a substantially planar configuration; and, a third energy attenuation element with a plurality of sidewalls that are arranged to form a hexagonal housing. A first crown gap is formed between the first and second energy attenuation elements. A second crown gap is formed between the second and third energy attenuation elements. A third crown gap is formed between an extent of the third and first energy attenuation elements. The crown energy attenuation assembly further includes a layer positioned adjacent to the plurality of sidewalls of the energy attenuation elements.

A helmet body includes an outer shell and an energy management liner with an outer shell lower edge extending between the inner surface and the outer surface of the outer shell. At least two shoulder pad recesses are positioned at a lower edge of the outer shell on a respective left and right sides of the helmet. The energy management liner is adjacent to the inner surface of the outer shell and includes at least two shoulder pads formed of a foamed energy management material. Each of the at least two shoulder pads is received into one of the at least two shoulder pad recesses on the respective left or right side of the helmet, each shoulder pad extending from inside of the outer shell to across at least a majority of a width of the lower edge of the outer shell.

A helmet, has a shell that includes a first portion and a second portion. The first portion has first, second and third layers. The second layer is positioned between the first layer and the third layer. The second layer is less dense than the first layer and the third layer. The second portion has a plurality of enemy dissipaters. Each of the energy dissipaters has a rod that extends in a spiraling manner from a fixed end to a free end. The rod tapers continuously along its length from the fixed end to the free end so that the fixed end exhibits a larger internal cross sectional area than the free end. The free end is capable of vibrating when the helmet is impacted by an object in order to dissipate impact energy.

A compressible liner for a helmet or other apparatus subject to shock loading comprises three substantially co-extensive layers mutually engaged by respective cone-like protuberances and cone-like recesses. The intermediate layer is of a different compressibility and provides for de-coupling of the layers in an oblique impact.

A garment worn by a wearer has an impact absorbing material comprising arrays of various hexagonal or other deformable polygonal-shaped structures positioned between an exterior surface and an interior surface. When force is applied to the exterior surface, the structures of the impact absorbing materials deform (e.g., buckle) in a desired manner, reducing the force received by the interior surface.

An integrally formed safety helmet structure includes an assembly of a helmet shell or a shell body, a foam filling body enclosed in the shell body and a structure body. Geometrical array texture structures are disposed at the assembling interfaces between the shell body, the structure body and the foam filling body. In manufacturing, by means of a mold or molding module and solid foaming technique, the foam filling body is integrally formed to bond with the shell body and the structure body and the geometrical array texture structures so as to form a compact and rigid multilayer complex reinforcement structure. The complex reinforcement structure not only can enhance the structural strength of the entire safety helmet, but also has the advantages of material-saving, lightweight, high security and easy manufacturing.

A helmet includes a shell having an interior surface and a padding configured to provide progressive impact resistance. The padding includes a first padding layer and a second padding layer. The first padding layer has a first side configured to conform to the interior surface of the shell and an opposing second side that defines a plurality of first continuous extensions arranged in a spaced configuration defining a plurality of first recesses therebetween. The second padding layer has a third side configured to conform to a head of a wearer of the helmet and an opposing fourth side that defines a plurality of second continuous extensions arranged in a spaced configuration defining a plurality of second recesses therebetween.