The present invention relates to the technical field of electric vehicles, and provides an posture vehicle, which comprises a vehicle body, two wheelers pivoted to the vehicle body, pedals installed on the vehicle body, and two driving components installed in the vehicle body and driving the two wheelers to rotate driven by the pedals. The driving components and the wheelers are in the same operating plane. Namely, in a using process, the user treads on the wheelers, thereby eliminating interference of a balance state of the vehicle body to an output signal of the driving components, and enhancing the sensitivity of the driving components for judging the balance signal.

An electric vehicle may comprise a board including first and second deck portions each configured to receive a left or right foot of a ride, a wheel assembly disposed between the deck portions and including a ground-contacting element, a motor assembly mounted to the board and configured to rotate the ground-contacting element around an axle to propel the electric vehicle, at least one sensor configured to measure orientation information of the board, and a motor controller configured to receive orientation information measured by the sensor and to cause the motor assembly to propel the electric vehicle based on the orientation information. The electric vehicle may include exactly one ground-contacting element, and the motor may be a hub motor.

The skateboard capable of providing the self-propulsive force includes: a board main body; a center rotation portion which allows a user of the skateboard to change a direction of the skateboard with one foot put thereon; a first footrest portion which is provided on one side of the board main body with respect to the center portion and moves the board main body through a left and right reciprocating movement of the footrest; a second footrest portion which is provided on the other side of the board main body with respect to the center portion and moves the board main body through a left/right reciprocating movement of the footrest; and an elastic guide portion which is provided between the board main body and the wheel assemblies and guides left/right reciprocating movements of the support members.

An accessory for a self-balancing board is provided. The self-balancing board comprises a foot-deck having two lateral foot-deck ends. Each lateral foot-deck end is coupled to a motor that drives a wheel in response to an orientation of the lateral foot-deck end relative to a horizontal plane. The accessory includes a chassis, at least one travel surface-contacting element coupled proximal to a first longitudinal end of the chassis to facilitate travel of the chassis over a travel surface, and a seat coupled to the chassis and configured to support a person. The accessory further includes a first foot-deck engagement element proximal to a second longitudinal end of the chassis distal to the first longitudinal end and constructed to engage the foot-deck of the self-balancing board proximal to the first lateral foot-deck end, and a second foot-deck engagement element proximal to the second longitudinal end of the chassis and constructed to engage the foot-deck of the self-balancing board proximal to the second lateral foot-deck end. At least one control member coupled to the first foot-deck engagement element and the second foot-deck engagement element controls the orientation of the lateral foot-deck ends relative to a horizontal plane via the first foot-deck engagement element and the second foot-deck engagement element.

An electric vehicle may comprise a board including first and second deck portions each configured to receive a left or right foot of a ride, a wheel assembly disposed between the deck portions and including a ground-contacting element, a motor assembly mounted to the board and configured to rotate the ground-contacting element around an axle to propel the electric vehicle, at least one sensor configured to measure orientation information of the board, and a motor controller configured to receive orientation information measured by the sensor and to cause the motor assembly to propel the electric vehicle based on the orientation information. The electric vehicle may include exactly one ground-contacting element, and the motor may be a hub motor.

An accessory for a self-balancing board is provided. The self-balancing board comprises a foot-deck having two lateral foot-deck ends. Each lateral foot-deck end is coupled to a motor that drives a wheel in response to an orientation of the lateral foot-deck end relative to a horizontal plane. The foot-deck has at least one sensor that is triggered when a rider is in a riding position thereon. The accessory includes a chassis, at least one travel surface-contacting element coupled proximal to a first longitudinal end of the chassis to facilitate travel of the chassis over a travel surface, and a seat coupled to the chassis and configured to support the rider. The accessory further includes an engagement structure that releasably engages the self-balancing board and fails to trigger the at least one sensor. At least one sensor-triggering element that is actuatable relative to the engagement structure between a first position is provided, wherein the at least one sensor-triggering element fails to trigger the at least one sensor, and a second position, wherein the at least one sensor-triggering element triggers the at least one sensor. At least one control member is coupled to and actuating at least one of the engagement structure and the at least one sensor-triggering element to control the orientation of the lateral foot-deck ends relative to a horizontal plane.

An accessory for a self-balancing board is provided. The self-balancing board comprises a foot-deck having two lateral foot-deck ends. Each lateral foot-deck end is coupled to a motor that drives a wheel in response to an orientation of the lateral foot-deck end relative to a horizontal plane. The foot-deck has at least one sensor that is triggered when a rider is in a riding position thereon. The accessory includes a chassis, at least one travel surface-contacting element coupled proximal to a first longitudinal end of the chassis to facilitate travel of the chassis over a travel surface, and a seat coupled to the chassis and configured to support the rider. The accessory further includes an engagement structure that releasably engages the self-balancing board and fails to trigger the at least one sensor. At least one sensor-triggering element that is actuatable relative to the engagement structure between a first position is provided, wherein the at least one sensor-triggering element fails to trigger the at least one sensor, and a second position, wherein the at least one sensor-triggering element triggers the at least one sensor. At least one control member is coupled to and actuating at least one of the engagement structure and the at least one sensor-triggering element to control the orientation of the lateral foot-deck ends relative to a horizontal plane.

A safe hovering skate board unit capable of being driven by a user is disclosed. The hovering skateboard includes a first board to receive the user, one or more first magnetic source, configured with the first board, to emit magnetic field, a second board magnetically coupled with the first board, one or more second magnetic source configured with the second board to repel the magnetic field and facilitate the first board to hover over the second board. Further, the unit includes the ground engaging wheels attached to the second board moves in the direction driven by the user. Furthermore, the unit may include a specialized safety system for ensuring safety of the user by controlling one or more components corresponding to the hovering skateboard unit based on one or more factors corresponding to the user. Further, a corresponding method of operating the hovering skate board unit is also disclosed.

An accessory for a self-balancing board is provided. The self-balancing board comprises a foot-deck having two lateral foot-deck ends. Each lateral foot-deck end is coupled to a motor that drives a wheel in response to an orientation of the lateral foot-deck end relative to a horizontal plane. The accessory includes a chassis, at least one travel surface-contacting element coupled proximal to a first longitudinal end of the chassis to facilitate travel of the chassis over a travel surface, and a seat coupled to the chassis and configured to support a person. The accessory further includes a first foot-deck engagement element proximal to a second longitudinal end of the chassis distal to the first longitudinal end and constructed to engage the foot-deck of the self-balancing board proximal to the first lateral foot-deck end, and a second foot-deck engagement element proximal to the second longitudinal end of the chassis and constructed to engage the foot-deck of the self-balancing board proximal to the second lateral foot-deck end. At least one control member coupled to the first foot-deck engagement element and the second foot-deck engagement element controls the orientation of the lateral foot-deck ends relative to a horizontal plane via the first foot-deck engagement element and the second foot-deck engagement element.

An electric vehicle may comprise a board including first and second deck portions each configured to receive a left or right foot of a ride, a wheel assembly disposed between the deck portions and including a ground-contacting element, a motor assembly mounted to the board and configured to rotate the ground-contacting element around an axle to propel the electric vehicle, at least one sensor configured to measure orientation information of the board, and a motor controller configured to receive orientation information measured by the sensor and to cause the motor assembly to propel the electric vehicle based on the orientation information. The electric vehicle may include exactly one ground-contacting element, and the motor may be a hub motor.