Provided herein are exemplary methods for reducing or preventing skull injury, the method comprising covering a human skull above all of or a first portion of a squamous temporal bone. Methods may also include covering the human skull with a first layer of material that reduces or prevents the first layer of material from contacting or impacting all of or a first portion of the squamous temporal bone. The first layer of material may be connected to a device or apparatus for supporting the first layer of material above or in close proximity to the all of or the first portion of the squamous temporal bone. Additionally, the method may include comprising covering the human skull above all of or a second portion of a squamous temporal bone.

A helmet is described herein. The helmet can be configured to hold the arms of a corresponding eyewear piece, such as an eyeglass or sunglass, through one or more features of the helmet. The helmet can further include an air deflector visor. The one or more features, such as one or more channels, allows for the helmet to receive and hold the eyewear of a wearer. Additionally, the helmet visor can utilize deflector vents to redirect airflow around the helmet for lower drag and/or deflect airflow to portions of the helmet to aid in the cooling of the wearer.

A skydiving helmet including a helmet shell having a front opening, is provided. The helmet further includes a visor having a lateral mounting section, where the visor is operable between a lowered position and a raised position. The skydiving helmet also includes a visor mounting system laterally positioned on the helmet shell to pivotally connect the lateral mounting section to the helmet shell. The visor mounting system includes a base plate having a cavity formed therein with a locking slot and a guiding section communicating with one another. The visor mounting system also includes a locking element positioned within the cavity and being operable between an extended configuration for preventing rotation of the visor, and a retracted configuration for allowing a frontward translation of the visor, away from the helmet front opening, and subsequent rotation of the visor, from the lowered to the raised position.

A helmet may include a helmet body, a fit system, a bezel, and a hardware retainer. The helmet body may have an outer shell and an energy management layer. The bezel may be separate from the outer shell and coupled to the helmet body at the vent opening of the helmet, encircle the vent opening, and have a hardware opening extending through the bezel and an anchor opening in the bezel adjacent the hardware opening. The hardware retainer may be positioned behind and coupled to the bezel. The hardware retainer may include a hardware receiving aperture aligned with the hardware opening and a hardware retainer cover coupled to a rear side of the hardware retainer. The hardware retainer may further include an anchor recess aligned with the anchor opening. The bezel may be in-molded into the energy management layer.

An electronic motorcycle helmet. The electronic motorcycle helmet includes a helmet having an aperture therein that can receive a head therethrough. A visor is disposed on a front side of the helmet and a display is disposed on an interior surface of the visor. A microprocessor, including a logic that receives a command input directed to one of a plurality of subsystems, toggles the subsystem between an activated state and a deactivated state, and displays a status window on the display corresponding to the subsystem. The plurality of subsystems includes a plurality of cameras disposed about the helmet, wherein each of the cameras is operably connected to the display and can apply a low-light filter for low-light conditions. Other subsystems include a wireless transmitter to wirelessly communicate with an external device, a GPS system, and a battery disposed at a lower edge of the rear side.

A helmet airflow control member includes a plate-like main body arranged on a shell and including a main body rear surface that covers part of a shell outer surface, and at least one passage formation portion arranged on the main body rear surface. A periphery of the main body rear surface includes a first peripheral portion, which is shaped in correspondence with the shell outer surface and closes a space between the main body rear surface and the shell outer surface, and a second peripheral portion, which is spaced apart from the shell outer surface and defines an opening of the space between the main body rear surface and the shell outer surface in cooperation with the shell outer surface. The passage formation portion defines a passage in the space, with the passage extending from the opening into the space and returning from the space to the opening.

A skydiving helmet including a helmet shell having a front opening, is provided. The helmet further includes a visor having a lateral mounting section, where the visor is operable between a lowered position and a raised position. The skydiving helmet also includes a visor mounting system laterally positioned on the helmet shell to pivotally connect the lateral mounting section to the helmet shell. The visor mounting system includes a base plate having a cavity formed therein with a locking slot and a guiding section communicating with one another. The visor mounting system also includes a locking element positioned within the cavity and being operable between an extended configuration for preventing rotation of the visor, and a retracted configuration for allowing a frontward translation of the visor, away from the helmet front opening, and subsequent rotation of the visor, from the lowered to the raised position.

A helmet with an outer shell, an inner liner, a plurality of vents, and an occipital cliff is disclosed. The outer shell includes an outer surface made up of a first and second surface, the first and second surfaces joined by a drop-off running across the outer surface from a left side of the helmet to a right side of the helmet. A majority of the drop-off is closer to a coronal plane bisecting the helmet than it is to the rear of the helmet. The drop-off is contained within a posterior section of the helmet defined by the coronal plane. The first surface defines a top of the drop-off and the second surface defines a bottom of the drop-off, such that the drop-off has a height. The occipital cliff is located at the rear end of the helmet and is approximately perpendicular to the second surface proximate the drop-off.

An electronic motorcycle helmet. The electronic motorcycle helmet includes a helmet having an aperture therein that can receive a head therethrough. A visor is disposed on a front side of the helmet and a display is disposed on an interior surface of the visor. A microprocessor, including a logic that receives a command input directed to one of a plurality of subsystems, toggles the subsystem between an activated state and a deactivated state, and displays a status window on the display corresponding to the subsystem. The plurality of subsystems includes a plurality of cameras disposed about the helmet, wherein each of the cameras is operably connected to the display and can apply a low-light filter for low-light conditions. Other subsystems include a wireless transmitter to wirelessly communicate with an external device, a GPS system, and a battery disposed at a lower edge of the rear side.

A helmet that includes vents in the shell and removable plugs that may be positioned in the vents to provide an airtight seal while maintaining the aerodynamic shape of the helmet. The vent has an outer vent opening in the outer wall surface of the shell and an inner vent opening in the inner wall surface of the shell. The plug includes a resilient lower surface and an upper surface opposite the resilient lower surface. The resilient lower surface has a lower peripheral lip that compresses when the plug is pushed through the outer vent opening and the inner vent opening and that subsequently expands after the lower peripheral lip passes through the inner vent opening so that the lower peripheral lip engages a portion of the inner wall surface of the shell. The upper surface has an upper peripheral lip configured to conform to a portion of the outer wall surface of the shell when the plug is inserted in the vent.