A footrest system for use on a snowmobile. The footrest system includes a footrest that extends from a first proximal end to a second distal end. A fender covers a proximal portion of the footrest to define a toe pocket. A snow evacuation bore passes through the proximal portion of the footrest and the fender. The snow evacuation bore is configured to pass snow out of the toe pocket and through the footrest and fender.

A footrest system for use on a snowmobile. The footrest system includes a footrest that extends from a first proximal end to a second distal end. A fender covers a proximal portion of the footrest to define a toe pocket. A snow evacuation bore passes through the proximal portion of the footrest and the fender. The snow evacuation bore is configured to pass snow out of the toe pocket and through the footrest and fender.

A two-seater off-road vehicle includes a travel vehicle body that is supported on the ground by a front wheel unit and a rear wheel unit, and a boarding part disposed above a vehicle body frame included in the travel vehicle body. The boarding part includes: a driver seat; a steering operation tool in front of the driver seat; and a passenger seat of a saddle seat type behind the driver seat.

A two-seater off-road vehicle includes a travel vehicle body that is supported on the ground by a front wheel unit and a rear wheel unit, and a boarding part disposed above a vehicle body frame included in the travel vehicle body. The boarding part includes: a driver seat; a steering operation tool in front of the driver seat; and a passenger seat of a saddle seat type behind the driver seat.

An anti-rotation bracket configured to engage a horizontal indented vehicle component and fit within an indentation formed within a component attachable to the vehicle is presented. The anti-rotation bracket comprises a flat region having an opening formed therein, the flat region sized to fit within the indentation and an extension integrally formed at a right angle to the flat region, the extension sized to engage the horizontal indented vehicle component such that the extension abuts the horizontal indented vehicle component, thereby inhibiting rotation of the anti-rotation bracket.

An anti-rotation bracket configured to engage a horizontal indented vehicle component and fit within an indentation formed within a component attachable to the vehicle is presented. The anti-rotation bracket comprises a flat region having an opening formed therein, the flat region sized to fit within the indentation and an extension integrally formed at a right angle to the flat region, the extension sized to engage the horizontal indented vehicle component such that the extension abuts the horizontal indented vehicle component, thereby inhibiting rotation of the anti-rotation bracket.

The present invention relates to a swing vehicle technical fields, and more particularly to a self-balance vehicle. It includes a main body of the self-balance vehicle, a first wheel and a second wheel, the first wheel and the second wheel is respectively installed at both sides of the main body of the self-balance vehicle, the outside of the first wheel is installed a folding first foot petal, the outside of the second wheel is installed a folding second foot petal. Compared with the prior art, in the self-balance vehicle of the present invention the first foot petal and the second foot petal can be overlapped, its volume is compact after folding, it is convenience for carry, its appearance is small and beautiful.

A vehicle propellable by a human comprising a front assembly having a front wheel and a pair of hand pedals connect thereto; a rear assembly having a first rear wheel and a second rear wheel rotatably connected thereto; a chest rest located between the front assembly and the rear assembly, the chest rest configured to support the chest of a rider lying forward on the vehicle; and a first foot support structure operatively coupled to rotate the first rear wheel, and a second foot support operatively coupled to rotate the second rear wheel wherein the first rear wheel and second rear wheel are independently rotated by opposite feet of a rider when said feet are within said first and second foot support, respectively.

A human-machine interaction somatosensory vehicle is provided. The human-machine interaction somatosensory vehicle may include a vehicle body and two wheels mounted on the vehicle body. The two wheels may rotate around the vehicle body in a radial direction. The vehicle body may include a support frame, two pedal devices mounted on the support frame, a controller, and a driving device configured to drive the two wheels. The support frame may be an integral structure rotatably connected to the two pedal devices. The two pedal devices each may include a pedal foot board and a first position sensor. The first position sensor may be mounted between the pedal foot board and the support frame, and configured to detect stress information of the pedal device. The controller may be configured to control the driving device to drive the two wheels to move or turn based on the stress information of the pedal devices.

A human-machine interaction somatosensory vehicle is provided. The human-machine interaction somatosensory vehicle may include a vehicle body and two wheels mounted on the vehicle body. The two wheels may rotate around the vehicle body in a radial direction. The vehicle body may include a support frame, two pedal devices mounted on the support frame, a controller, and a driving device configured to drive the two wheels. The support frame may be an integral structure rotatably connected to the two pedal devices. The two pedal devices each may include a pedal foot board and a first position sensor. The first position sensor may be mounted between the pedal foot board and the support frame, and configured to detect stress information of the pedal device. The controller may be configured to control the driving device to drive the two wheels to move or turn based on the stress information of the pedal devices.