A scooter, which is driven by an electric motor, for transporting persons, includes an electric drive motor and a standing platform. A front wheel is arranged along a center axis of the standing platform. A steering rod is coupled to the front wheel. Handlebars pivot the front wheel about a rotational axis, which is formed by the steering rod. Two rear wheels are at a spacing from the front wheel and are each arranged laterally offset with respect to the center axis. A feed-through aperture, which is preferably completely closed circumferentially and is passed through by the steering rod, or in which the front wheel sits, is incorporated into the standing platform. The front wheel is flanked on both sides in each case by at least one support element which projects from an underside of the standing platform that faces an underlying surface.

A scooter, which is driven by an electric motor, for transporting persons, includes an electric drive motor and a standing platform. A front wheel is arranged along a center axis of the standing platform. A steering rod is coupled to the front wheel. Handlebars pivot the front wheel about a rotational axis, which is formed by the steering rod. Two rear wheels are at a spacing from the front wheel and are each arranged laterally offset with respect to the center axis. A feed-through aperture, which is preferably completely closed circumferentially and is passed through by the steering rod, or in which the front wheel sits, is incorporated into the standing platform. The front wheel is flanked on both sides in each case by at least one support element which projects from an underside of the standing platform that faces an underlying surface.

The present disclosure provides a scooter. The scooter includes a scooter body and a photographing portion; the photographing portion is mounted on the scooter body; and the scooter body is provided with an avoidance space for avoiding a photographing view angle of the photographing portion, so that the photographing portion photographs a road condition around the scooter body.

The present disclosure provides a scooter. The scooter includes a scooter body and a photographing portion; the photographing portion is mounted on the scooter body; and the scooter body is provided with an avoidance space for avoiding a photographing view angle of the photographing portion, so that the photographing portion photographs a road condition around the scooter body.

A turning mechanism and a handle. The turning mechanism comprises: a first connecting rod (201) and a second connecting rod (202); the first connecting rod (201) is provided with a first bevel end, the second connecting rod (202) is provided with a second bevel end, and the second bevel end matches with the first bevel end, so that the second connecting rod (202) rotates along the end face of the first bevel end; in the rotating process, the first bevel can be attached to the second bevel, so that no gap exists between the first connecting rod (201) and the second connecting rod (202).

A self-balancing robot system providing AI humanoid robots or robot vehicles comprising a drive wheel propulsion system configured to achieve mobility and balance by means of sensoring system components, accelerometers, and trajectory algorithms. The self-balancing robot system components include; a computer control system with processors and memory, a motion control system, an autonomous drive system, a wireless communication system comprising I/O system processes including WIFI, Bluetooth, and a smartphone, a network system, and a user interface control.

A self-balancing robot system providing AI humanoid robots or robot vehicles comprising a drive wheel propulsion system configured to achieve mobility and balance by means of sensoring system components, accelerometers, and trajectory algorithms. The self-balancing robot system components include; a computer control system with processors and memory, a motion control system, an autonomous drive system, a wireless communication system comprising I/O system processes including WIFI, Bluetooth, and a smartphone, a network system, and a user interface control.

An outrigger sail vehicle system includes: a vehicle, such as a bicycle; and an outrigger sail device, including a mounting base connected to the vehicle, an outrigger arm rotatably connected to the mounting base, a boom handle rotatably connected to the outrigger arm; a sail assembly, including a sail frame with first and second frame members, and a sail member that is spanned out by the sail frame; whereby, the sail assembly is rotatable from a right to a left side of the vehicle.

An outrigger sail vehicle system includes: a vehicle, such as a bicycle; and an outrigger sail device, including a mounting base connected to the vehicle, an outrigger arm rotatably connected to the mounting base, a boom handle rotatably connected to the outrigger arm; a sail assembly, including a sail frame with first and second frame members, and a sail member that is spanned out by the sail frame; whereby, the sail assembly is rotatable from a right to a left side of the vehicle.

An electric self-balancing vehicle including a top cover, a bottom cover, an inner cover, a rotating mechanism, two wheels, two hub motors, a plurality of sensors, a power supply, and a controller is described herein. The top cover includes a first top cover and a second top cover disposed symmetrically and rotatable relative to each other. The bottom cover is fixed to the top cover and includes a first bottom cover and a second bottom cover disposed symmetrically and rotatable relative to each other. The inner cover is fixed between the top cover and the bottom cover and includes a first inner cover and a second inner cover disposed symmetrically and rotatable relative to each other. The rotating mechanism is fixed between the first inner cover and the second inner cover. The two wheels are rotatably fixed at two sides of the inner cover, respectively. The two hub motors are fixed in the two wheels, respectively. The plurality of sensors is disposed between the bottom cover and the inner cover, respectively. The power supply is fixed between the first bottom cover and the first inner cover. The controller is fixed between the second bottom cover and the second inner cover, the controller is electrically connected with the plurality of sensors, the power supply, and the hub motors, and the controller controls the hub motors to drive the corresponding wheels to rotate according to sensing signals transmitted by the sensors.