A face device for monitoring biomedical parameters of a user provides a support and housing structure shaped so as to be applied to the head of the user, an oximetry sensor fitted to the support and housing structure so as to adhere, in an operating position, to the face of the user at the facial artery, a sound source fitted to the support and housing structure so as to adhere, in an operating position, to a cranial bone of the user, an independently powered electronic board for processing data, received in the support and housing structure and connected to the oximetry sensor and to the sound source so as to detect and process signals coming from the oximetry sensor and to provide information on biomedical parameters to the user acoustically through the sound source. This face device does not engage or distract the user.

A protective helmet includes an upper section and a lower section; each having inner and outer facing surfaces; a gap formed between the upper and lower sections; at least one connection member connecting the upper section to the lower section and maintaining the gap; the upper section being movable with respect to the lower section when an impact force is applied to the outside surface of the upper section; an inner shell securable to the inner facing surface of the lower section; the inner shell being adapted to receive a portion of the helmet user's head, whereby the head of the user will be spaced from the inner facing surface of the upper section when the portion of the user's head is received in the inner shell; and the inner shell substantially preventing the user's head from making contact with the inner facing surface of the upper section.

A protective helmet includes an upper section and a lower section; each having inner and outer facing surfaces; a gap formed between the upper and lower sections; at least one connection member connecting the upper section to the lower section and maintaining the gap; the upper section being movable with respect to the lower section when an impact force is applied to the outside surface of the upper section; an inner shell securable to the inner facing surface of the lower section; the inner shell being adapted to receive a portion of the helmet user's head, whereby the head of the user will be spaced from the inner facing surface of the upper section when the portion of the user's head is received in the inner shell; and the inner shell substantially preventing the user's head from making contact with the inner facing surface of the upper section.

In one embodiment, a zero impact head gear is provided including an outer helmet and an inner helmet. The outer helmet has forward and rear retaining stops protruding from the interior of the outer helmet. The inner helmet has a forward and rear retaining stops protruding from the inner helmet to allow movement of the inner helmet within the outer helmet, but capable of limiting a forward displacement the inner helmet with respect to the outer helmet.

One embodiment of a helmet 10, upon which markers 14 are used to add decorations to the plastic outer shell 12. The ink from the markers 14 dries quickly, and thereafter becomes waterproof and unable to be removed without the use of chemicals or without damaging the plastic outer shell 12 of the helmet 10. The decorations thus applied are able to withstand the expected rigors of sporting activity without being erased. In addition, a solvent based cleaning solution 18 and a means for applying the solvent based cleaning solution 18 to the plastic outer shell 12 of the helmet 10 is used to erase any mistakes in the decorations, or to erase them entirely, thereby allowing the user to re-decorate the helmet 10 whenever they so desire.

The present disclosure seeks to reduce the effects of rotational and linear acceleration experienced by the body of a user in response to an impact force. Modular disengaging systems of the present disclosure are generally suitable for coupling to protective equipment to provide a disengaging motion between various layers such that the effects of the impact force to the body of the user are reduced. Generally described, the modular disengaging systems of the present disclosure include layers configured to facilitate relative lateral motion therebetween upon an impact force.

The present disclosure seeks to reduce the effects of rotational and linear acceleration experienced by the body of a user in response to an impact force. Modular disengaging systems of the present disclosure are generally suitable for coupling to protective equipment to provide a disengaging motion between various layers such that the effects of the impact force to the body of the user are reduced. Generally described, the modular disengaging systems of the present disclosure include layers configured to facilitate relative lateral motion therebetween upon an impact force.

Novel and advantageous masks and helmets to protect an athlete's head and face from impacts and injuries. In particular, the present disclosure relates to novel and advantageous masks and helmets to help protect a baseball or softball catcher's face and head from concussive forces of an incoming ball strike. A mask of the present disclosure may be coupled to a helmet, or may be configured for use without a helmet in some embodiments. The mask may provide a generally cone-shaped structure in front of a wearer's face, so as to provide an angled surface for contact with an incoming ball. Additionally, a shock absorbing material may be provided at an interface between the helmet and mask to reduce and distribute force transfer between the mask and the helmet.

Novel and advantageous masks and helmets to protect an athlete's head and face from impacts and injuries. In particular, the present disclosure relates to novel and advantageous masks and helmets to help protect a baseball or softball catcher's face and head from concussive forces of an incoming ball strike. A mask of the present disclosure may be coupled to a helmet, or may be configured for use without a helmet in some embodiments. The mask may provide a generally cone-shaped structure in front of a wearer's face, so as to provide an angled surface for contact with an incoming ball. Additionally, a shock absorbing material may be provided at an interface between the helmet and mask to reduce and distribute force transfer between the mask and the helmet.

The present disclosure generally provides oral inserts useful for determining forces experienced by a user, such as a human user, to the head, for example, by measuring one or more of acceleration, velocity, displacement, or rotation. In some aspects, the disclosure provides oral inserts that, when worn properly by a human user, calculate the forces experienced by the user's head with high accuracy. In some aspects, the disclosure provides systems for detecting and calculating forces experienced by the user's head and to determine whether such forces are above a certain threshold indicative of increased concussion risk. In some aspects, the disclosure provides methods for calculating forces experienced by the user's head and determining whether such forces are above a certain threshold indicative of concussion.