A man-machine interaction somatosensory vehicle includes a vehicle body and two wheels provided on the vehicle body. The wheels are able to rotate around the vehicle body in a radial direction. The vehicle body further comprising a supporting frame, two pedal devices provided on the supporting frame, a control device, and a driving device for driving the wheels. The supporting frame is of an integral structure and being rotatably connected to the wheels. The pedal devices includes a pedal foot board and a first position sensor located between the pedal foot board and the supporting frame and used for sensing the stress information on the pedal devices. The control device controls, according to the stress information on the two pedal devices, the driving device to drive the wheels to move or steer.

Systems and methods directed to a steering column clamp for securing a steering column to a steerer tube are provided. The steering column clamp may include an internal clamp portion having longitudinal slot disposed at least partially between a first end of the internal clamp portion and a second end of the internal clamp portion. The steering column clamp may include a tightening mechanism, when engaged, causes the internal clamp portion to compress about a steerer tube placed in a first end of the internal clamp portion. The steering column claim may also include an exterior wall portion at least partially enclosing the internal clamp portion such that a hollow portion is between the internal clamp portion and an internal surface of the exterior wall portion of the steering column clamp.

Provided are a self-balancing scooter and a control method thereof, and a kart powered by the same. The self-balancing scooter includes two scooter bodies on which foot boards and motorized wheels are disposed, and a rotating shaft device, where the rotating shaft device includes a rotating shaft, two axle seats, and a torsion limiting mechanism. The torsion limiting mechanism controls a rotation angle by the fit between a limiting portion on the rotating shaft and a fitting portion on one axle seat. The present disclosure realizes torsion limit by directly using the rotating shaft and the axle seats without the use of an additional element (for example, a limiting shaft), thus simplifying the structure of the rotating shaft device and facilitating assembly.

A personal mobility device (PMD) has a footboard unit including a footboard, a front wheel disposed on the footboard, and a rear wheel disposed behind the front wheel on the footboard. The PMD also has a steering unit including a steering axle, a fixation unit that connects one end of the steering axle to the footboard unit, and a grip disposed on the other end of the steering axle. The PMD also has a side guard disposed on each side of the footboard unit and extending along an axial direction of the footboard.

An electric vehicle includes a stem and a base with wheels. The base is at a first end of the stem, with symmetrical elements of the base opposed across a stem axis. Elements on each side include a wheel, a drive motor, a platform and pivot joints. The wheel has an axis of rotation. The drive motor is connected to the wheel. The platform is between the wheel and the stem. A first pivot joint connects the stem and the platform. A second pivot joint connects the platform and the wheel. In a first orientation, the platforms are substantially perpendicular to the stem and in a second orientation the platforms are substantially parallel to the stem. The wheel axes are substantially parallel to each other and are substantially perpendicular to the stem axis in the first orientation and the second orientation.

A vehicle includes a body and a cover rotatably connected to the body. The vehicle further includes a control bar rotatably connected to the cover. The cover is rotatable onto the body to put the cover in the stowed position from an extended position. The bar is between the cover and the body when the bar is in the stowed position.

The application relates to a pedal mechanism and a housing of a balancing vehicle. The pedal mechanism comprises a pedal body, and an internal framework is arranged inside the pedal body. A lower side of the pedal body is also formed with an induction probe for inducting a control system inside a balancing vehicle. A housing of the balancing vehicle comprises a pair of symmetrically arranged and relatively rotatable inner housings, the inner housings are connected with the upper housing, and the pedal mechanism installed at upper housing. The pedal body and the induction probe are integrally molded, which has the advantages of less multiple assembly processes, shorter processing time, higher precision, and not easy to fall off which strengthens the stability of the structure.

A system includes an emergency response vehicle transitionable between a motive state and a non-motive state and a tool. The tool includes an identifier and is configured to be removably secured to the emergency response vehicle. The system further includes a scanner coupled to the emergency response vehicle and operable to identify the identifier when the tool is secured to the emergency response vehicle. A control module is communicatively coupled to the scanner and includes a processor and a memory storing instructions which cause the processor to determine that the emergency response vehicle has transitioned between the motive state and the non-motive state, and, in response to determining that the emergency response vehicle has transitioned between the motive state and the non-motive state, cause the scanner to scan the emergency response vehicle for the identifier to determine whether the tool is secured to the emergency response vehicle.

Systems and methods are disclosed herein for an interchangeable electric scooter with seating option for 2 passengers is proposed. The assembly provides various advancements including but not limited to a glossy finish, a rectangular front frame member, an aerodynamic manual brake fin, a communication device support member, floor and front panels having multiple colors and designs, On/Off digital locking system, front and back cameras, solar panel, retractable umbrella, cell phone charging spot and holder, Bluetooth connectivity, GPS enabled, smart helmet, an integrated router forming a Wi-Fi hotspot, a daytime running lamp and back lit lights, number plate, a help switch, a sound system, a camera for livestream and social media synchronization, a communication device charger, an integral GPS.

A balance scooter startup method and an apparatus controlling balance scooter startup, the balance scooter startup method comprising the following steps: for a balance scooter in a powered-off state, sensing back and forth rocking motion, and rotating an electric motor to generate electricity, and outputting an electrical signal; the electrical signal triggering a power supply module of a control board to start; a battery of the power supply module starting to power the balance scooter, completing the balance scooter startup. The apparatus controlling balance scooter startup is used to detect rocking motion of the balance scooter, rocking of wheels drive the electric motor to generate electricity, and collection of the electrical signal generated by the electric motor controls the balance scooter to start up. The present disclosure is convenient for a user to employ, and improves a usage experience for a user.