The present invention is directed to a protective sports helmet including a crown energy attenuation assembly positioned within a crown region of the helmet shell. The crown energy attenuation assembly 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 sports helmet kit has a shell, attachable face guard, composite helmet liner, and fit pods to improve and customize the fit of the helmet to the wearer. The composite liner consists of a base liner and a selected group of fit elements, for example, fit pods, removably attached to the inner surface of the base liner (i.e., the surface of the base liner facing the wearer's head). The fit pods are selected from a set of fit pods having different properties, for example, different sizes, thicknesses, densities, and cross-sections. The selection of fit pods from the set may be aided by taking anatomical measurements of the wearer's head and analyzing the measurements with respect to the geometry of the helmet to produce a pressure map. The measurements may be taken by physical contact or by non-contact means. The fit pods may be selected to optimize a pressure map, and thus optimize the fit, for a given wearer of the helmet.

A protective impact device is provided that produces an approximately constant force during compression. The device distinguishes several structural features. First, the cross-sectional area in between two impact surfaces increases over the stroke distance when compression takes place. Second, a compressible fluid containing vessel, held in between two impact surfaces, defines an outer shape with a positive second derivative slope defined from one impact surface towards the other impact surface. Third, orifices allow the fluid to bleed out from the compressible vessel when an impact force causes compression of the protective impact device. The resulting approximately constant force scales more or less linearly with impact energy, regardless of impact velocity caused by the impact force. Applications include athletic equipment, automotive bumpers, aircraft landing gear, and any other application that would benefit from maximum energy absorption during an impact.

A snore blocking helmet for comfortably minimizing snore impact on others includes a helmet body having a front portion, a rear portion, a right portion, a left portion, a top portion and a bottom perimeter forming an inside. The front portion has a visor aperture and a plurality of vent apertures extending through to the inside. A visor is rotatably coupled to the helmet body to cover and alternatively uncover the visor aperture. A plurality of fans is coupled within the inside adjacent the plurality of vent apertures. A control housing is coupled through the front portion. A plurality of controls is coupled to the control housing and is in operational communication with the plurality of fans. A power source is coupled to the control housing and is in operational communication each of the plurality of controls and the plurality of fans.

A protective helmet with first and second helmet sections each including an outer shell section and an inner layer section of protective material. The first and second helmet sections are displaceable relative to one another to adjust a size of the helmet. Two opposed side protective members are received inwardly of the outer shell sections on opposed sides of the helmet. Means for adjusting a position of the side protective members relative to the inner layer sections of protective material are provided. The means are configured such that, when the protective helmet is adjusted when on the head of the wearer, the protective members remain substantially stationary with respect to the head of the wearer when the inner layer sections are displaced with the first and second helmet sections.

A modular helmet system with a removable/detachable/interchangeable exterior shell, an inner force-absorbing layer releasably connected to the rigid exterior shell layer, and a multiple fastening devices associated with the shell which allow the shell to be interchanged/replaced/reconfigured at will. The shell as a single piece unit, or combinable components bear the fastening devices designed to enable rapid, secure interchange of the helmet system's layers, therefore allowing the helmet to be adapted for climatic, functional, and aesthetic preferences.

The present disclosure is generally related to systems, devices, and methods for mitigating energy propagation through helmets during a collision, thereby reducing the risk of brain damage from a traumatic brain injury. For example, an impact absorption system may be utilized to increase energy absorption of forces propagating through a helmet. In a particular configuration, the absorption system includes an external shell, a plurality of impact absorbing elements, one or more liners, and/or a foam layer to mitigate the resulting forces from an impact that reach a user's brain.

A headband with one or more protective inserts. The inserts may be strategically positioned to provide protection for specific areas of a person's head that are most vulnerable to impact, depending on the sport or other activity. The inserts may be directly attached to the headband, or may be enclosed in pouches which are directly attached to the headband. The headband may be worn with or without additional headgear, and may be configured to cooperate with the additional headgear as to form, fit, and functionality.

Systems and methods of a safety helmet for protecting the human head against repetitive impacts, moderate impacts and severe impacts so as to significantly reduce the likelihood of both translational and rotational brain injury and concussions may be provided. The helmet may include an outer shell, an outer liner disposed within and coupled to the outer shell, and an inner liner disposed within and coupled in spaced opposition to the outer liner. A damper array may allow for omnidirectional movement of the inner liner relative to the outer liner and the outer shell.

Helmet padding systems are disclosed. One helmet padding system includes a rigid shell configured to cover a top of a user's head and be worn under a piece of headgear. The rigid shell includes a first pair of slots configured to extend in a direction from a back of the user's head toward a front of the user's head when the rigid shell is worn on the user's head. The first pair of slots define a central portion and opposed side portions of the rigid shell. The central portion includes at least one flap extending from the central portion across one of the first pair of slots and covering a first region of one of the opposed side portions of the rigid shell. A spacing pad is positioned within the rigid shell.