A flex cell for absorbing energy from an applied force includes a panel attached to a flex cage. The flex cage is made from a resilient material that allows deformation of the flex cage when a force is applied to the flex cell. The flex cell is attachable to a support surface. In some instances, the flex cell is detached from the support surface when sufficient force is applied to the flex cell.

An impact protecting cap for use under a helmet having a cap portion made from a resiliently deformable material that is fitted directly over the head of an intended user and secured in place by a resiliently deformable band. The cap has its inner surface covered with a plurality of energy absorbing resiliently deformable modules that are evenly distributed across the cap. The modules are made of a pliable material.

An impact-related acceleration reduction helmet which includes an outer shell with at least one aperture formed therethrough, an insulating layer, at least one cushioning pad, and at least one damper, wherein the at least one damper is secured within the at least one aperture of the outer shell and is configured to reduce at least the linear and/or rotational acceleration of the helmet caused by a force applied to the helmet.

A protective headgear having a protective outer layer, an inner impact dispersing layer, an opening in the posterior of the helmet to allow hair to exit the protective helmet, and juxtaposed to the posterior opening, a flap that covers a portion of the opening and is selectively attachable to the inner impact attenuating layer.

A protective headgear having a protective outer layer, an inner impact dispersing layer, an opening in the posterior of the helmet to allow hair to exit the protective helmet, and juxtaposed to the posterior opening, a flap that covers a portion of the opening and is selectively attachable to the inner impact attenuating layer.

A helmet that includes a subliner shell comprised of a hard impact resistant material. The shell has inner and outer surfaces. A subliner element having a first foam pad having a top surface and a bottom surface. The top surface is attached to the inner surface of the shell. A second foam pad is constructed of an energy absorbing viscoelastic foam material that is radially partitioned into individual segments. The segments are nested with respect to each other such that the nested segments have side surfaces in slidable direct contacting engagement with side surfaces of adjacent nested segments. The second foam pad has a top surface attached to the bottom surface of the first foam pad. A third foam pad has a top surface and a bottom surface, with the top surface of the third foam pad being attached to the bottom surface of the second foam pad.

The present invention provides an apparatus to dissipate and attenuate mechanical waves which travel through a human brain upon blunt trauma. The apparatus comprises a pressurizable and ventable outer balloon shell encasing an inner hard shell. The pressurizable and ventable outer balloon shell is configured to release a pressurized gas to the atmosphere upon an impact to said pressurizable and ventable outer balloon shell. The apparatus is configured to enhance efficiency in reduction of an amplitude of the mechanical waves of the blunt trauma delivered to the human brain and to disrupt doubling-up of mechanical waves in a pressure zone inside the pressurizable and ventable outer balloon shell. The apparatus is configured to ventilate the pressurizable and ventable outer balloon shell and the inner hard shell.

A helmet having an energy absorbing layer, an outer layer that is harder than the energy absorbing layer and a plurality of outer plates mounted on the outer surface of the outer layer is provided. The outer plates on the outer layer can slide across the outer layer. A low friction interface between the outer surface of the outer layer and at least a part of the outer surface of the outer plates contacts the outer surface of the outer layer under an impact.

A flex cell for absorbing energy from an applied force includes a panel attached to a flex cage. The flex cage is made from a resilient material that allows deformation of the flex cage when a force is applied to the flex cell. The flex cell is attachable to a support surface. In some instances, the flex cell is detached from the support surface when sufficient force is applied to the flex cell.

Protective headgear apparatus (such as a helmet used for contact sports) is formed to comprise a non-rigid outer shell in the form of multiple layers of open-cell foam, each layer having a different density. A flexible, lightweight metal frame (i.e., a “cage”) is disposed to contact the inner surface of the outer shell (i.e., bonded in a manner that essentially “locks” the frame to the foam layer), and an open-cell foam cushion layer (in a waffle-like pattern) is bonded to the exposed surface of the metal frame. The various foam layers are preferably impregnated with activated carbon particles that electrostatically absorb (i.e., “capture”) the energy caused by blows to the outer shell. The captured energy is thereafter distributed throughout the volume of the foam layer itself, so as to minimize the amount of energy that reaches the wearer's head.