A surgical garment configured for attachment to a surgical helmet, wherein the surgical garment defines a barrier between the wearer and the environment. The surgical helmet includes a peripheral device, a chin bar, and a coupling member. The coupling member may be recessed within the chin bar. The surgical garment may comprise an attachment element configured to removably couple with the coupling member of the surgical helmet. The coupling member and attachment member may comprise reciprocal features, such as a protrusion and a recess. The protrusion and/or corresponding recess may comprise a curved or similarly shaped surface configured to resist decoupling of the attachment member and the coupling member when a force is applied to the surgical garment.

A surgical garment configured for attachment to a surgical helmet, wherein the surgical garment defines a barrier between the wearer and the environment. The surgical helmet includes a peripheral device, a chin bar, and a coupling member. The coupling member may be recessed within the chin bar. The surgical garment may comprise an attachment element configured to removably couple with the coupling member of the surgical helmet. The coupling member and attachment member may comprise reciprocal features, such as a protrusion and a recess. The protrusion and/or corresponding recess may comprise a curved or similarly shaped surface configured to resist decoupling of the attachment member and the coupling member when a force is applied to the surgical garment.

Aspects of the subject disclosure may include, for example, a process in which a helmet system including a machine is provided, that when worn by a user, positions the machine in a proximate relationship to a head portion, a neck portion, or both of the user. The helmet system provides a redistributing of a force responsive to a collision received along a first direction, wherein the force results from kinetic energy of an impact encountered at an external surface of the helmet system. The force induces an actuation of the machine, wherein the redistributing of the received collision force is based on the actuation of the machine. Energy transferred to the head portion, the neck portion, or both, resulting from the kinetic energy of the impact, is reduced, e.g., absorbed, based on the actuation of the machine. Other embodiments are disclosed.

A method for testing a helmet for effectiveness of user protection includes moving a load along a predetermined path, supporting a target body at an impact location in the predetermined path, the target body including a head model and a helmet disposed on the head model, and impacting the target body with a force generated by the moving of the load. The impacting of the target body entails contacting the target body with an impactor free to move perpendicularly and tangentially relative to a surface of the target body. The supporting of the target body is at least reduced, if not eliminated, before or during the impact of the impactor with the target body at the location. Forces generated are automatically measured or sensed during the impact of the impactor with the target body at the location.

A safety system is configured to be worn by a user. The safety system includes a helmet, a transparent display screen coupled to the helmet and configured to provide eye safety for the user, the transparent display screen configured to display graphical information to the user in substantially real time. According to one embodiment, if a hazard is identified in a first route, the apparatus communicates an identification of the hazard for display to the user via the transparent display screen. Further, if the hazard is identified in the first route, the apparatus communicates an identification of a second route for display to the user via the transparent display screen, the second route avoiding the hazard with each of the first route and the second route rendered in the transparent display screen. According to various embodiments, the apparatus operates in substantially real time to evaluate conditions in the first route based on information provided by the at least one sensing system to determine whether the hazard exists.

The present system provides a lightweight fire-resistant photoluminescent identifier system for firefighters, which is suitable for use on the firefighter's facemask, as well as other equipment. The system is lightweight and provides individual recognition of an individual firefighter. The identifier system lights up automatically in a low-light environment without batteries, yet prevents glare to the firefighter using the system. The components that comprise the system are fire-resistant to temperatures up to and exceeding 500 degrees Fahrenheit to facilitate personal recognition of the individual in dark and low-light areas.

A mounting rail assembly comprises a rail configured to be coupled to a helmet. The rail may include a rear surface and a front surface with a mounting groove extending along a length of the front surface. The mounting groove may be open outwardly from a front surface of the rail and be configured to couple to a first accessory device at two or more positions along the length of the rail. A recess may be proximate an edge of the mounting rail assembly. The recess may be open generally perpendicular to the mounting groove and configured to receive a second accessory device. At least a portion of the recess may be positioned between the mounting groove and the rear surface of the rail.

A mounting rail assembly comprises a rail configured to be coupled to a helmet. The rail may include a rear surface and a front surface with a mounting groove extending along a length of the front surface. The mounting groove may be open outwardly from a front surface of the rail and be configured to couple to a first accessory device at two or more positions along the length of the rail. A recess may be proximate an edge of the mounting rail assembly. The recess may be open generally perpendicular to the mounting groove and configured to receive a second accessory device. At least a portion of the recess may be positioned between the mounting groove and the rear surface of the rail.

A headset for a hydration system is disclosed. The headset includes a fluid conduit adapted to connect to a distal end of a hydration system supply tube, and a magnetic quick connect having an upstream and a downstream coupling member. The upstream and downstream coupling members have a common mating axis and together define a portion of the fluid conduit. The upstream member also includes an off-axis arm that may be rotated about the mating axis without decoupling the coupling members. A headgear mount for use in headsets for hydration systems, such as the disclosed headset, is also provided.

Remote monitoring of a subject wearing a sports helmet is enabled. In one aspect, an example system includes a safety helmet and a sensor integrated with the helmet for continuously gathering head acceleration force data, the head acceleration force data associated with the head movements of a subject. The system can also include a wireless transceiver coupled to the sensor for transmitting the head acceleration force data and a mobile device for receiving the head acceleration force data from the wireless transceiver. The system can further include a database engine for displaying the head acceleration force data to a user.