A vehicle including a front module including a front wheel and a rear module selectively moveably connected to the front module, the rear module including a rear wheel. The vehicle further includes an electric motor assembly, a mode selector, at least one extension assembly connected between the front module and the rear module for selectively extending and retracting to provide a selective variation in an overall length of the vehicle; and a vehicle control unit being communicatively connected between the mode selector and the electric motor assembly. The vehicle control unit performs a method for selectively changing the overall vehicle length. The method includes receiving from the mode selector an indication to change the overall length, determining that the front wheel is rotationally locked, and causing an electric motor to drive the rear wheel such that the rear module translates relative to the front module.

A vehicle includes: an electric prime mover; a frame member acting as a load bearing member of the vehicle; and a structural member functionally connected to the frame member. The structural member is capable of supporting the electric prime mover rotatably. The electric prime mover includes a shaft fixedly mounted to the structural member and that is disposed substantially in a lateral direction of the vehicle. The shaft fixedly supports a stationary member of the electric prime mover and the shaft rotatably supports a rotating member of the electric prime mover. A cable assembly extends outward from the stationary member through a cable path defined by the shaft. The cable path includes a portion provided with a caulking member capable of securely holding the cable assembly thereat. The cable assembly includes an external sheath forming at least an outer periphery of the cable assembly.

A personal mobility vehicle comprising a control unit for controlling a steering function of the vehicle, wherein the control unit is adapted to receive route information from a personal smart device and to control the vehicle at least semi-autonomously based on the route information.

One variation of a system includes: a cam block mounted to a deck of a scooter and defining cam lobes arranged about a pivot feature and cam heels between the set of cam lobes; a pivot block pivotably coupled to the pivot feature and defining followers riding over the cam lobes; a pair of wheel uprights locating a pair of wheel assemblies; a first lateral link extending between and coupled to the pair of wheel uprights and pivotably coupled to the pivot block; a second lateral link extending between and coupled to the pair of wheel uprights, vertically offset from the first lateral link, and coupled to the pivot block between pair of wheel uprights; and a spring element driving the followers of the pivot block into cam heels to bias the second lateral link toward a neutral position.

Embodiments of the present disclosure relate to a chassis for a two-wheeler. The chassis includes a first downtube and a second downtube and a battery mounting system. The battery mounting system includes a movable battery housing configured to house a battery under a seat of the two-wheeler and move between a closed position and an open position, at least two support members configured to support the movable battery housing, and at least one pivot hinge coupled to a front side of the movable battery housing and supporting the movable battery housing. The at least two support members and the at least one pivot hinge are configured to enable an angular movement of the movable battery housing with respect to a seat axis between the open position and the closed position, thereby enabling replacement of the battery located under the seat of the two-wheeler, while maintaining a closed seat position of the seat.

A parking and charging station for electric vehicles, the parking and charging station has a small footprint and data transfer capability. The electric vehicles may include e-bikes and e-scooters, but other similar vehicles may also be supported. The parking and charging station may include a vertical automatic and motorized conveyor. The parking and charging station may include a standalone vertical post with one or more bars attached horizontally.

A personal mobility vehicle, such as a scooter, includes at least one battery and motor for powering at least one driven wheel. The vehicle also includes a braking assembly configured to isolate the motor from the at least one driven wheel such that power is terminated from the motor to the at least one wheel in response to a user engaging a braking assembly of the vehicle. The vehicle can include a switch or position sensor that interacts with the braking assembly to initiate the isolation of the motor from the at least one driven wheel and the switch or position sensor preferably is inaccessible to the foot of the user.

A vehicle includes a fender, a storage compartment, and a first retaining wall. The fender has an inner surface, an outer surface, and a through hole connecting the inner surface and the outer surface. The storage compartment has a bottom plate. The bottom plate of the storage compartment is located at a side of the outer surface of the fender and at least covers the through hole. The fender is located below the storage compartment in a top-bottom direction of the vehicle. The first retaining wall is disposed on the outer surface of the fender and surrounds at least a portion of the through. A portion of the first retaining wall is closer to a front of the vehicle than the through hole in a front-rear direction of the vehicle.

A personal transport vehicle is provided, which includes a front wheel assembly having a front rim and a front tire seated on the front rim, and a rear wheel assembly having a rear rim and a rear tire seated on the rear rim. The vehicle also includes a motor disposed within the rear rim of the rear wheel assembly and coupled to a mount of the rear rim, where the motor is configured to rotate the rear tire to cause movement of the personal transport vehicle. The vehicle further includes a frame coupled to the front wheel assembly and to the motor disposed within the rear wheel assembly, and a steering arm coupled to the front wheel assembly within the front rim for controlling movement of the front tire for steering the personal transport vehicle.

A bake-steering apparatus for controlling autonomous navigation of an electric scooter includes at least one electric motor coupled to at least one wheel of the scooter to provide driving power to enable forward momentum of the scooter, at least a pair of brake pads on the scooter such that each brake pad is adapted to make mechanical braking contact with respective ones of the wheels to provide navigational steering of the scooter, and a computational module on the scooter and electrically connected to each brake pad. The computational module is adapted to receive electrical signals and compute them into corresponding braking commands so as to determine the mechanical braking contact to generate corresponding slowing and turning of the forward momentum of the scooter so as to provide navigational steering of the scooter.