An electric vehicle includes a frame, a wheel coupled to the frame, and a battery assembly including a housing supported by the frame. The housing includes a top side and a bottom side opposite the top side. A drive assembly of the electric vehicle is at least partially enclosed within a drive housing unit. The drive assembly includes a motor configured to receive power from the battery assembly and a gear assembly configured to transmit torque from the motor to the wheel. The drive housing unit is positioned below the bottom side of the housing.

Methods and systems for activating electric vehicles are provided. One method includes, in response to a first command to activate the vehicle, transitioning the vehicle from an inactive state to a wake state where a controller of the vehicle is activated and the vehicle is prevented from being propelled by an electric motor of the vehicle. The method also includes, in response to receiving a second command to activate the vehicle after receiving the first command, transitioning the vehicle from the wake state to a ready state where the vehicle is permitted to be propelled by the electric motor.

A bike includes a frame elongated in a longitudinal direction, a front fork rotatably engaged with a front wheel at a front end of the bike, a rear fork rotatably engaged with a rear wheel at a rear end of the bike, a handlebar supported for rotation at the front end of the frame for steering the bike, and a drive module configured to drive the rear wheel of the bike when operated selectively with power. The frame includes a down tube extending downward and rearward from the front end of the bike and a drive module enclosure formed at a second end of the down tube. The drive module enclosure defines a drive module receptacle that is open along the longitudinal direction of the bike. The drive module receptacle is sized to receive the drive module along the longitudinal direction of the bike.

A running bike that can be operated selectively with and without power. The running bike includes a front fork rotatably engaged with a front wheel, a rear fork rotatably engaged with a rear wheel, the rear fork having an upper portion and a lower portion, and a handlebar rotatably engaged with the front fork for steering the running bike. A frame extends between and connects the front fork and the rear fork. The frame includes a down tube having a first end connected to the front fork and a second end opposite the first end and positioned adjacent the rear fork, a top tube connected to and extending between the down tube and the upper portion of the rear fork, and a drivetrain receiving region defined as an area rearward of the down tube, forward of the rear wheel, and below the top tube.

Embodiments of the present disclosure include a wireless remote control or remote control application for controlling the lighting of an electronic personal transportation vehicle. Embodiments can solve problems related to sharing electronic personal transportation vehicles by uniquely identifying a user, and allowing that user to control the lighting of the electronic personal transportation vehicle. In this manner, other users can control the lighting at different times, depending on the specific person that is using the electronic personal transportation vehicle at any given time.

Collision alert systems and methods for micromobility vehicles include a proximity sensor, a speed sensor, a warning device, and a controller having a bypass mode and a warning mode. The controller compares the speed of the micromobility vehicle with a predetermined speed threshold, enters the bypass mode when the speed of the micromobility vehicle is less than the predetermined speed threshold, and enters the warning mode when the speed of the micromobility vehicle is greater than the predetermined speed threshold. The controller does not activate the warning device in the bypass mode. In the warning mode, the controller calculates an estimated time until a potential collision with the object, compares the estimated time object with a predetermined time threshold, and generates a collision warning by activating the warning device in response to the estimated time until collision being less than the predetermined time threshold.

Systems and methods for customizing one or more performance characteristics of a vehicle are provided. The systems and methods may be used with electric powersport vehicles and may facilitate expanded customization capabilities and a wide range of operator experiences available with the vehicle. A method of operating an electric vehicle includes receiving, via an operator interface, a value of an individually-variable parameter defining a propulsive performance characteristic of the electric vehicle, and, when the electric motor is driven to propel the vehicle, regulating an output of the electric motor based on the value of the individually-variable parameter.

A self-powered motorcycle or bicycle includes: a pair of shock absorber frame housings (101), each having a cylindrical hollow inside, a closed upper end portion, a split space formed at a lower end portion, rack gear moving holes (101a) respectively formed in both sides of the outer wall in a longitudinal direction, and self-powered generators (100) respectively mounted on both sides of the outer wall, the pair of shock absorber frame housings being mounted to face each other; a pair of shock absorber frames (102); disc-shaped partitions (102c) fixed in a horizontal direction; anti-rotation protrusions (104a) formed at both sides of the spring guide in a longitudinal direction; and anti-rotation protrusion guide holes (102b) formed at both sides of the shock absorber frame.

A saddled electric vehicle (1) having a battery (100) that is attachable to and detachable from the vehicle (1) includes a vehicle electronic lock (220) which enables the vehicle (1) to be locked and unlocked, a lock control unit (320) which controls the vehicle electronic lock (220), and a sub battery (327) which supplies electric power to the lock control unit (320), in which the lock control unit (320) enables the vehicle to be unlocked in a state in which the battery (100) is removed from the vehicle (1).

The present disclosure relates to a telescopic rod, a steering device and an electric luggage box. The telescopic rod comprises a hollow first tube, a second tube sleeved outside the first tube and being slidable relatively to the first tube, a positioning mechanism configured to lock and unlock the first tube in position relative to the second tube, and a control member configured to control the positioning mechanism to lock and unlock in position, wherein the positioning mechanism comprises a pushrod connected to the control member and movable in the first rube, an abutment unit provided at a bottom end of the pushrod, and a positioning unit adapted for being abutted by the abutment unit for locking and unlocking in position; the first tube has a limiting structure provided therein, for limiting a space for movement of the abutment unit. The steering device comprises a handle and the afore-mentioned telescopic rod connected to the handle. The electric luggage box comprises a ridable box body, a front wheel and a rear wheel mounted on the box body, and the afore-mentioned steering device for steering the front wheel.