A brake device for a vehicle with at least one wheel, wherein the wheel defines a rotational axis, with a brake body device for the transmission of a brake force to the wheel, with a concentric brake cylinder for the generation of the brake force. The brake cylinder has an inner housing part for radial support on a wheel axle of the wheel and an outer housing part for axial support on the brake body device. The two housing parts can be moved relative to one another, and a pressure chamber which runs around the rotational axis is formed between the two housing parts. The brake device has an insulation device for the thermal insulation of the brake body device in the direction of the brake cylinder. The insulation device is arranged at least axially between the outer housing part and the brake body device.

A device includes a magnet and a magnetic field sensor configured to sense a magnetic field of the magnet. The magnet and the magnetic field sensor are arranged to be movable relative to each other. A relative movement between the magnet and the magnetic field sensor is based on a movement of a throttle controller of a vehicle. A power provided by a motor of the vehicle correlates to a position of the magnet relative to the magnetic field sensor as sensed by the magnetic field sensor.

An electric drive motorcycle (100) allows a suitable configuration of all the components deputed to the electric supply of the motorcycle electric drive, and comprises: a front portion comprising one or more front wheels (103) and a handlebar (104); a rear portion comprising a saddle (101), a shell body (107) arranged below said saddle (101), and a rear wheel (105) arranged below said shell body (107); an intermediate portion (108) extending as a connection between said front portion and said rear portion; an electric drive unit (8) connected to said rear wheel (105); and a hybrid supply unit supplying said electric drive unit (8), comprising at least a battery unit (115) and a combustion engine (116) actuating an electric generator (120) apt to supply said battery unit (115) and/or said electric drive unit (8), wherein said shell body (107) defines a housing space apt to receive at least said battery unit (115) and said combustion engine (116), with the related electric generator (120), placed side by side therebetween.

The present disclosure provides a scooter. The scooter includes a scooter body, a driving portion, a wheel portion, a photographing portion and a control portion; the driving portion is connected with the scooter body; at least part of wheel portion is movably connected with the driving portion; the photographing portion is connected with the scooter body, so that an environment around the scooter body is photographed through the photographing portion; the control portion is connected with the scooter body; the control portion is electrically connected with the photographing portion and the wheel portion; and the control portion controls the driving portion according to a signal collected by the photographing portion, thereby driving the at least part of wheel portion to drive the scooter body to move and avoid an obstacle.

In some embodiments, a scooter comprises a deck configured to support a rider, a front wheel and a rear wheel, a head tube, a steering column, and a foot brake. The steering column can include a steering tube and a handlebar assembly, and the steering column can be used to steer the scooter by controlling a direction of the front wheel. The foot brake can be configured to apply a braking force to the rear wheel when the foot brake is pressed down. A plurality of neck members can connect the deck to the head tube.

An electric mobility apparatus is disclosed. The electric mobility apparatus may include a mid-frame assembly in which a bracket fastened to at least one component is mounted on an inner side, a front frame assembly having a portion inserted into a front face of the mid-frame assembly so as to be coupled to the mid-frame assembly, and a tail frame assembly having a portion inserted into a rear face of the mid-frame assembly so as to be coupled to the mid-frame assembly, wherein the bracket is fastened to both side faces inside the mid-frame assembly.

Various battery arrangement structures are presented for a saddle-riding type vehicle. An arrangement can be configured to protect a battery from external impact, and can include a pair of left and right rear frames disposed at the rear section of the vehicle with a battery disposed between the pair of left and right rear frames. The pair of left and right rear frames include a pair of left and right first rear frames and a pair of left and right second rear frames. A power unit-supporting portion which swingably supports a power unit is provided at rear portions of the pair of left and right rear extension portions, and the battery is disposed between the pair of left and right second rear frames and above the power unit-supporting portion.

The present invention is generally directed to a swing arm configuration and, more specifically, a swing arm that is supported by a shaft of a motor, such as an electric motor of a motorcycle. The configuration includes a swing arm assembly that is supported by a shaft of a motor at one end and a rear axle at the other end. Advantageously, the shaft of the motor may be a structural component of an electric motorcycle and serve as the swing arm pivot as well as the drive shaft.

A personal mobility that adjusts power supply based on a state of a kickstand is provided. The personal mobility includes a main body, a kickstand provided rotatably on one end in the main body, and a variable resistor that is provided on an axis of the kickstand as an axis. The variable resistor is configured to output a voltage that varies based on a position of the kickstand. A controller is then configured to adjust power supply when the position of the kickstand is a parking position.

A personal mobility and a control method are provided. The personal mobility includes: a main body; a front wheel mounted on the front end of the main body; a pair of rear wheels mounted on the rear end of the main body; an actuator configured to adjust a distance between the pair of rear wheels; an image data device mounted on the personal mobility and having a field of view outside of the personal mobility, the image data device configured to acquire image data; and a controller configured to determine at least one of user state information or external environment information based on the image data, and control the actuator to adjust the distance between the pair of rear wheels based on at least one of the user state information or the external environment information.