Guard padding with sensor is provided, including a cushion pad and a sensor. The cushion pad has auxetic structure and is manufactured by a 3D printing process. The cushion pad has a slot at a side thereof. The sensor manufactured by the 3D printing process is disposed in the slot. The sensor is a pressure sensor, a humidity sensor or a temperature sensor. The pressure sensor generates a pressure signal, the humidity sensor generates a humidity signal and the temperature sensor generates a temperature signal.

Aspects of the subject disclosure may include, for example, a protective shell having an exterior surface and an interior surface and a lever assembly positioned between the interior surface of the protective shell and a portion of a body. The lever assembly includes a lever having an elongated member extending between a first end and a second end and a pivot location. A fulcrum pivotally engages the pivot location of the lever, wherein the lever rotates about the fulcrum in response to an impact force applied along a first direction to the exterior surface of the protective shell. The lever assembly further includes a spring engaging the lever, wherein a rotation of the lever deforms the spring in a second direction to absorb a portion of a kinetic energy of the collision to redirect and reduce a transfer of a portion of force to the body. Other embodiments are disclosed.

A visual shock indicator apparatus includes a helmet, a facemask secured to the helmet, and a mounting element secured to the helmet. The mounting element has a mounting region disposed between a pair of attachment points used to secure the facemask to the helmet. A retainer assembly is configured to be removably coupled to the mounting element within the mounting region. The retainer assembly includes a shock indicator configured to provide a visual indication of receipt of a predetermined level of a shock event.

Methods and systems for motorcycle communication are disclosed, including a) storing contacts, vertical angle limit (VAL), and/or a timer in memory; b) monitoring; c) determining detection of impact; d) if detected, then determining motorcycle condition, turning on visual and audible indicators, determining location, and communicating location and/or condition to a contact; e) if not detected, then determining if exceeded VAL; f) if exceeded, then beginning timer, concurrently monitoring timer and VAL, and determining whether timer has completed; g) if not completed, then continue concurrent timer and VAL monitoring until timer has completed; h) if completed, then determining if VAL exceeded; i) if not exceeded, then returning to step (b); j) if exceeded, then determining the motorcycle condition, turning on the visual and audible indicators, determining location, and communicating location and/or condition to a contact; and k) if not exceeded, then returning to step (b). Other embodiments are described and claimed.

A helmet with an airbag assembly coupled to the shell of the helmet. The airbag assembly includes an airbag and an inflation device. The inflation device is configured to at least partially inflate the airbag upon deployment of the airbag assembly. The helmet also includes a processing circuit disposed at least partially within the shell. The processing circuit is configured to receive helmet data regarding a second helmet, transmit deployment data regarding inflation of the airbag assembly, and control operation of the inflation device to inflate the airbag based on the helmet data.

The present invention relates to a helmet and a method for dealing with an accident using the helmet, which the helmet includes: a helmet body part made of a resin having a semi-spherical space for receiving the head of a wearer; a light part arranged in the front of the helmet body part having LEDs mounted on a substrate to provide the wearer with lighting; a metallic heat radiator extending from the front of the helmet body part to the back thereof along the upper central line of the helmet body part and partially contacting the back of the substrate to discharge heat; a communication device part received in the helmet body part for dealing with communication and emergency circumstances; and a battery received in the helmet body part for supplying power to the communication part and light part. According to the present invention, the metallic heat radiator is integrated with the resinous helmet body part by injection molding of different materials, so that the heat generated from the LEDs of the light part is discharged upwards from the top of the helmet, thus preventing the wearer from being subjected to the discomfort caused by the heat generated from the LEDs.

A smart helmet system includes a helmet and a mobile communication device. The smart helmet includes a helmet body, a detection module and a wireless transmission module. The detection module is applied to detect at least one motion parameter of the helmet. The wireless transmission module is to transmit the motion parameter. The mobile communication device stores an operation regulation to define at least one predetermined operation function of the mobile communication device corresponding to at least one set motion track. The mobile communication device is to receive the motion parameter to accordingly determine a detected motion track and further to activate the predetermined operation function when the detected motion track is complied with the set motion track, so as to operate the mobile communication device according to the predetermined operation function.

In an aspect, an accessory for an activity is provided, and includes an accessory housing, an impact detection device and a secondary module. The impact detection device includes at least one impact sensor selected from the group of sensors comprising an accelerometer and a gyroscope. The secondary module includes at least a battery configured for powering both the impact detection device and the secondary module. The impact detection device and secondary module together further include a microcontroller and a memory. The impact detection device is removably connectable to the secondary module and is connectable to another secondary module in another protective accessory.

A protective system including: a protective suit capable of withstanding the force of an impact without tearing, the protective suit including: a head portion; a neck portion connected to the head portion; a torso portion connected to the neck portion; a fluid bladder formed in at least two of the head portion, neck portion and torso portion, the fluid bladder containing a fluid; and an alert indicator for indicating when the force of an impact on the fluid bladder exceeds a predetermined threshold.

Protective headgear for use in dangerous and/or hazardous locations may comprise: a headgear shell; a locator device on the headgear shell for providing location data; a motion sensor on the headgear shell for providing motion data; a memory on the headgear shell and having a unique identifier stored therein and configured to store the location data and the motion data; a transmitter-receiver for transmitting the location data, the motion data and the unique identifier to a remote database and for receiving notification data therefrom; and a user interface responsive to the received notification data to provide a visual notification or an audible notification or a physical notification or a combination thereof.