A human-machine interaction somatosensory vehicle includes the vehicle body and wheels mounted on the vehicle body. The vehicle body includes the supporting frame, a control board, sensors, a battery, and pedal components. The wheels are mounted on the supporting frame. The pedal components are mounted above the supporting frame. The sensors are mounted below the pedal components. The battery supplies power to the control board. The control board controls the wheels to rotate according to signals of the sensors.

A cargo-carrying wheeled vehicle, said vehicle comprising: at least a cargo hold chassis (10); at least a rider support chassis (20) configured to be operatively behind said cargo hold chassis (10), in that, said cargo hold chassis (10) and said rider support chassis (20) cooperate to maintain centre of gravity of said vehicle, after addition of cargo to said cargo hold chassis (10) and after addition of rider to said rider support chassis (20), to obtain a naturally balanced position for said vehicle in a loaded as well as an unloaded condition,

An electric snowmobile that can reduce a load locally applied to a body frame is provided. The electric snowmobile includes a body frame, a right ski and a left ski, a track mechanism, a steering shaft, an electric motor, and a battery. The body frame includes a shaft support frame that rotatably supports the steering shaft, a front frame that extends forwardly and downwardly from the shaft support frame, and a rear frame that extends rearwardly and downwardly from the shaft support frame. The battery is supported by the front frame and the rear frame such that at least a portion of the battery is disposed in a region formed by a line connecting the front frame, the rear frame, a lower end of the front frame, and a lower end of the rear frame in a side view.

A saddled electric-powered vehicle is configured by including approximately rectangular parallelepiped batteries, a battery case in which the batteries are housed, battery-side terminals provided on bottom surfaces of the batteries, and case-side terminals engaged with the battery-side terminals. The battery case is arranged below a seat, and pressing holders that press the batteries housed in the battery case from above are provided while making a front and rear pair for each battery. The battery case is formed in a bottomed box shape with an upper side open. Each pressing holder is provided with a rubber portion brought into contact with an upper surface of each battery. The saddled electric-powered vehicle can enhance convenience by optimizing an arrangement and a housing structure of portable batteries.

A straddle-type electric vehicle includes two approximately rectangular parallelepiped batteries, a battery case in which the batteries are housed, battery-side terminals provided on bottom surfaces of the batteries, and case-side terminals engaged with the battery-side terminals. The two batteries are arranged next to each other in a vehicle width direction. An operation lever for connecting or separating the battery-side terminals and the case-side terminals to/from each other is provided. The operation lever is arranged in a middle in the vehicle width direction between the two batteries, and the battery-side terminals and the case-side terminals are arranged nearer outer sides in the vehicle width direction. A pair of front and rear link mechanisms for coupling the operation lever and the case-side terminals to each other is provided in front of and behind the battery case.

A foldable electric scooter and a manufacture method of the same. The foldable electric scooter includes a main body assembly, a front fork assembly located at the front end of the main body assembly, a rear fork assembly located at the rear end of the main body assembly, a telescoping plate assembly located on top of the front fork assembly and a handlebar assembly located on top of the telescoping plate assembly. The foldable electric scooter has a double headset design that increases a rake angle for more steering stability while still keeping the steering upright for an upright holding of the handlebars. The foldable electric scooter is manufactured by stamping of flat plate material.

The present disclosure provides a method for controlling an electric scooter and electric scooter, wherein the method comprises: a first target operation performed on the electric scooter is detected in a case that the electric scooter is unlocked by using a target account; the electric scooter is set to be in a temporarily locked state in response to the first target operation, wherein the electric scooter in the temporarily locked state is set to allow to be unlocked only by the target account within a target duration after detecting the first target operation the electric scooter in the temporarily locked state is unlocked in a case that a second target operation performed on the electric scooter is detected within the target duration. The present disclosure solves the problem existed in the method for controlling an electric scooter in the related art that the electric scooter is easily used by others when the electric scooter is temporarily stopped using.

A handlebar apparatus for an electronic vehicle including e-bikes and e-scooters. The handlebar apparatus includes an elongated handlebar having tubular handle portions. The apparatus further includes an electronic device housed within a casing of the handlebar. The handlebar apparatus includes sensors for receiving a throttling input and a braking input. The electronic device can perform most of the electronic operations of the electronic vehicle including receiving the throttling input and braking input and sending commands to the powertrain and braking assembly of the electronic vehicle.

Disclosed are a personal mobility and a control method thereof. The personal mobility includes a front body on which a front wheel is installed, and a rear body slidably coupled to the front body in a front-rear direction to enable wheelbase adjustment and on which a rear wheel is installed.