A management system for a micro mobility vehicle, includes a service vehicle which is configured to travel along a movement path, wherein the service vehicle includes an accommodation slot for accommodating the micro mobility vehicle, and is configured for exchanging power with the micro mobility vehicle when the micro mobility vehicle is accommodated in the accommodation slot; and a management server configured to communicate with the micro mobility vehicle and the service vehicle to determine a location and a charging amount of the micro mobility vehicle and configured to manage charging and arrangement of the micro mobility vehicle by guiding the service vehicle to allow the micro mobility vehicle to be accommodated in the service vehicle or withdraw the micro mobility vehicle from the service vehicle.

The field of the art to which the present invention refers is that of mechanical devices which can be universally fixed on the side of electric wheelchairs, on mobility scooters or in general on other electric mobility devices on wheels, for the precision parking of the devices and for their inductive electric charge. The invention is so that, when the part a, integral with the electrical device, is inserted in the part β, integral with a fixed point perpendicular to the floor (wall, pole, etc. . . . ), the receiving wireless plate (installed on part a) is in a position of precise alignment to the transmitting wireless plate (installed on part β) and the correct technical distance required for the activation of the inductive charging process and/or for the additional bidirectional communication of parameters and operating data. The invention can be mounted on any light electric mobility devices with wheels and to every vertical surface.

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.

A method and system for providing an electric transport device charging and cleaning station is described. In one embodiment, a method for providing an electric transport device to a user includes receiving a request from a user for an electric transport device. The method also includes preparing the electric transport device for deployment, including cleaning and/or charging the electric transport device. The method further includes deploying the prepared electric transport device to the user.

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.

Systems and methods are disclosed for coordinating and executing bidirectional energy transfer events between electrified vehicles and one or more participating electrified recreational vehicles. Energy may be transferred from an electrified vehicle to one or more electrified recreational vehicles, from the one or more electrified recreational vehicles to the electrified vehicle, or both during bidirectional energy transfer events. The proposed systems and methods may further be configured to provide various charging configurations between the electrified vehicle and the one or more electrified recreational vehicles.

A robot charging system and a control method thereof are provided to determine a charged state and charge a robot through self-driving. The robot charging system includes: a server configured to store boarding information of a user; a robot configured to receive the boarding information from the server, move the user to a destination included in the boarding information by self-driving using charged power, determine a discharge of the power, and move to a charging station for charging; and the charging station provided with a power supply coil to wirelessly supply the power source to the robot, and provided with a moving rail on a top of the power supply coil to sequentially charge a plurality of robots.

The method of parking and charging the individual vehicle providing for reception by the control center of parking stations territorial network of information from the individual vehicle user about stop waypoints for vehicle parking and charging along his planned route, establishment of communication between the user and control unit of this parking station, mating the electric connector of the vehicle battery with the connector of the parking station parking/charging terminal, charging the battery and storage of the vehicle, testing the charged condition of the battery and operability of the electric vehicle, time control of vehicle connection/disconnection to/from parking terminal, provides mutual settlements between the user and parking operator, and also engages the lock to fix the vehicle at the parking terminal and disengages the lock to ensure use of the vehicle.

A use management device includes: a traveling information acquisition part which acquires subsequent prospective traveling information about an electrically driven cart; a remaining amount information acquisition part which acquires remaining amount information about a battery; a determination section which determines, based on the prospective traveling information and the remaining amount information, whether charging of the battery is necessary; and a control section which executes a permission control of permitting a traveling motor to drive when the determination section determines that the charging of the battery is unnecessary, and executes a forbidding control of forbidding the traveling motor from driving when the determination section determines that the charging of the battery is necessary.

A small electric vehicle includes: left and right motors connected so as to respectively transmit power to left and right driving wheels; left and right rotation speed sensors; a joystick-type operation element; and a control unit, wherein it is configured to calculate target rotation speeds of the left and right motors, based on a target vehicle speed and a target vehicle angular velocity that are provided according to an operation position of the operation element, and control the left and right motors such that the actual rotation speeds of the left and right motors follow the respective target rotation speeds, and configured to update at least one target value, according to a cumulative number of travels obtained by dividing, by a predetermined control unit, a cumulative total value of a cumulative power consumption obtained by the battery management unit.