An apparatus having a mounting system and a helmet mounted display. The mounting system including a mounting plate and a mounting rocker. The helmet mounted display including a housing; latching tabs; an optical element having a combiner surface; at least one processor; and at least one memory including software, the at least one memory and software configured to, with the at least one processor, cause the apparatus at least to display heads up information on the combiner surface. The optical element is housed within a second portion of the housing being hingedly attached to the first portion of the housing. The apparatus is configured such that the combiner surface is positionable within the field of view of a wearer of the helmet. Related assemblies and methods are described.

An apparatus having a mounting system and a helmet mounted display. The mounting system including a mounting plate and a mounting rocker. The helmet mounted display including a housing; latching tabs; an optical element having a combiner surface; at least one processor; and at least one memory including software, the at least one memory and software configured to, with the at least one processor, cause the apparatus at least to display heads up information on the combiner surface. The optical element is housed within a second portion of the housing being hingedly attached to the first portion of the housing. The apparatus is configured such that the combiner surface is positionable within the field of view of a wearer of the helmet. Related assemblies and methods are described.

The disclosure relates to a bone conduction-based Bluetooth wireless riding helmet comprising a helmet body, a regulator at an interior of the helmet body, a brim at a front end of the helmet body, and a drawstring connecting two sides of a bottom of the helmet and the drawstring is fixed on the helmet through a quick release buckle; wherein an interior of the helmet body is provided with a removable bone conductor that is electrically connected with a power system and a control system; wherein the control system is electrically connected with a regulating device on the drawstring. The disclosure has the following beneficial effects. On the bone conduction-based helmet, a bone conduction-based vibrator sound source is embedded on each side of the helmet and perfectly integrated with the helmet, so that sounds can be clearly heard even when both ears of a rider are covered and even when it is used in a noisy environment.

The disclosure relates to a bone conduction-based Bluetooth wireless riding helmet comprising a helmet body, a regulator at an interior of the helmet body, a brim at a front end of the helmet body, and a drawstring connecting two sides of a bottom of the helmet and the drawstring is fixed on the helmet through a quick release buckle; wherein an interior of the helmet body is provided with a removable bone conductor that is electrically connected with a power system and a control system; wherein the control system is electrically connected with a regulating device on the drawstring. The disclosure has the following beneficial effects. On the bone conduction-based helmet, a bone conduction-based vibrator sound source is embedded on each side of the helmet and perfectly integrated with the helmet, so that sounds can be clearly heard even when both ears of a rider are covered and even when it is used in a noisy environment.

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.

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.

A helmet accessory mounting system includes a mounting device configured to couple to an outer surface of a side of a helmet. The mounting device includes a plurality of mounting locations configured to removeably couple to at least one accessory. A plurality of the plurality of mounting locations each includes an electrical node. A power supply is coupled to the mounting device. An electrical supply line electrically couples the power supply to each of the electrical nodes and the electrical supply line is contained at least partially within the mounting device.

A helmet accessory mounting system includes a mounting device configured to couple to an outer surface of a side of a helmet. The mounting device includes a plurality of mounting locations configured to removeably couple to at least one accessory. A plurality of the plurality of mounting locations each includes an electrical node. A power supply is coupled to the mounting device. An electrical supply line electrically couples the power supply to each of the electrical nodes and the electrical supply line is contained at least partially within the mounting device.

The exemplary embodiments herein provide an assembly for transmitting vibrations to a helmet worn by a user, including an annular element adapted to adhere to an outer surface of the helmet. The exemplary embodiments also include an assembly which rotationally connects with the annular element and comprises a bottom housing having a floor, teeth near the floor which engage with the annular element, and a sidewall extending upwardly around the circumference of the circular base unit. The embodiments further include a top housing having an outer sidewall that fits outside of the sidewall of the bottom housing and a plurality of apertures in a top surface; a pressure transducer placed atop the floor; and a mechanical user interface placed above the PCB and having at least one button which extends upwardly and through one of the apertures on the top surface of the top housing.

The exemplary embodiments herein provide an assembly for transmitting vibrations to a helmet worn by a user, including an annular element adapted to adhere to an outer surface of the helmet. The exemplary embodiments also include an assembly which rotationally connects with the annular element and comprises a bottom housing having a floor, teeth near the floor which engage with the annular element, and a sidewall extending upwardly around the circumference of the circular base unit. The embodiments further include a top housing having an outer sidewall that fits outside of the sidewall of the bottom housing and a plurality of apertures in a top surface; a pressure transducer placed atop the floor; and a mechanical user interface placed above the PCB and having at least one button which extends upwardly and through one of the apertures on the top surface of the top housing.