Embodiments are directed toward a comfort liner for a helmet. The comfort liner preferably includes a latticed structure configured to couple to the helmet. The latticed structure is preferably elastically compressible and configured to prevent rotation of the helmet relative to a wearer's head in at least one dimension.

Embodiments are directed toward a helmet liner coupler for coupling a helmet liner in a helmet. The coupler preferably includes a base and a plug. The plug preferably extends away from the base. The plug is preferably configured to engage in an interference fit with a female tubular member in the helmet. The base is preferably configured to engage the helmet liner and thereby couple the helmet liner to the helmet.

The present invention is directed to a protective sports helmet including a helmet shell, a face guard and an internal padding assembly positioned within the helmet shell. The internal padding assembly includes a brow pad having a first peripheral connection portion and a second peripheral connection portion. The internal padding assembly also includes a first jaw pad having an upper connection portion that mates with the first connection portion of the brow pad, and a second jaw pad having an upper connection portion that mates with the second connection portion of the brow pad. The internal padding assembly also includes a crown assembly with pad elements that include an internal separation layer that partitions the element into a first inflatable section and a second un-inflatable section. The connection portion of the jaw pads also mates with frontal pad elements of the crown assembly. The internal padding assembly further includes an occipital pad assembly that engages the helmet wearer's head below the occipital bone.

Articles including protective gear for a variety of sports and activities provide protection from one or both of linear and angular forces that either directly or indirectly impact the gear when it is donned. The articles include at least two layers of material that provide multimodal energy dissipation to minimize the extent of transmission of impact forces to tissue.

A helmet body includes an outer shell having an inner surface, an outer surface, and an outer shell lower edge extending between the inner surface and the outer surface, the outer shell further comprising at least two shoulder pad recesses positioned at a lower edge of the outer shell on a respective left and right sides of the helmet; and an energy management liner adjacent to the inner surface of the outer shell and comprising at least two shoulder pads formed of a foamed energy management material, each of the at least two shoulder pads received into one of the at least two shoulder pad recesses on the respective left or right side of the helmet.

A cycling helmet includes an outer shell and a closed cell foam layer adjacent to the outer shell. The cycling helmet also includes an inner liner adjacent to the closed cell foam layer. The cycling helmet further includes an insert of energy absorbing material adjacent to the inner liner. The insert is configured to move in multiple directions in response to an impact to the cycling helmet.

A helmet assembly includes an upper member, a lower member, and rigid or semi-rigid plates connected between the two members. The helmet may include a series of fluidly connected air compartments beneath the plates is disclosed. Embodiments of the helmet may dissipate impact energy in multiple ways including deformation of the plates, shifting of the plates, cushioning of the plates against a resilient compressible material present in the upper member, compression of air within the air compartments, movement of air within the air compartments, and/or expansion of air in non-impacted sections of the air compartments which causes the shifting of non-impacted plates. Springs with or without resilient, compressible inserts may be positioned between movable plates and a frame member. A spine including compressible material may extend along a top section of the helmet and connect plates on opposite sides of the helmet.

A hard hat and related impact protection layer is shown. The hard hat includes one or more feature to improve support of the impact protection layer. The impact protection layer is designed to improve impact energy absorption provided by a crushable material located within the hard hat shell.

An impact reducing headgear is disclosed which utilizes dynamically responsive materials which undergo physical changes during exposure to impact forces, such that physical changes or phase changes absorb energy. The helmet may be constructed with a dual shell structure and a bladder, where the dynamically responsive materials may be contained. An embodiment for a comfortable fit which remains tight to the wearer's head is disclosed.

A helmet including a body, an outer shell having an inner surface and an outer surface and a plurality of shock absorbers, the shock absorbers being positioned internal of the outer shell. A first set of shock absorbers has a first shock absorption characteristic and a second set of shock absorbers has a second shock absorption characteristic, the second shock absorption characteristic being different than the first shock absorber.