A compact mobility device has an adjustable drive mode. The device includes a base panel and a number of drive wheels rotatably provided at opposite ends of the base panel. The drive wheels are configured to rotate by receiving torque from a driving unit. A column is constituted by a plurality of links connected in series to be foldable and is configured such that a lower end of a lower link is rotatably coupled to the base panel with an upper end of an upper link being provided with a steering handle. An auxiliary wheel is provided between the links constituting the column and is configured to roll along with the drive wheels by coming into contact with a ground when the links are folded.

The present invention relates to a foldable tricycle, operable between a first mode of operation steerable by a tricycle rider, and a second mode of operation steerable by an attendant pushing the tricycle. The tricycle comprising: a pair of rear wheels; a foldable seat comprising a chair and a back support, for accommodating said tricycle rider; a foldable arm rest, connected to said foldable seat; a parental handle, for steering said tricycle by said attendant pushing the tricycle; a main frame, configured to rotatably hold said rear support, to support said foldable seat, to rotatably support said rider handle, to rotatably support said fork; and a latching mechanism, capable of locking and unlocking the rotatable movement, of the rear support, in relations to the main frame.

In an aspect, a compactable bicycle is provided, comprising a base frame portion and a steering structure. The base frame portion includes a seat tube and a head tube, a connecting tube connecting them and a rear frame portion that has a rear wheel mounted thereto. The steering structure includes a steering member rotatably mounted in the head tube, a handlebar, and a front wheel support having a front wheel connected thereto. The steering member includes first and second portions that are removably connectable together. The head tube includes first and second portions that hold the first and second steering member portions respectively. The second head tube portion is movable relative between a first position in which the first steering member portion is superjacent to the second steering member portion, and a second, stowage position.

Disclosed is a self-balancing scooter with a foldable foothold for an additional rider. The self-balancing scooter includes: a housing; a controller mounted inside the housing for controlling running and direction change; motors respectively mounted at both sides of the housing; wheels respectively mounted on shafts of the motors; a battery mounted on the bottom surface of the housing; a riding board mounted on the upper part of the housing to allow a main rider to put feet; a foldable foothold attached to the side wall of the riding board to allow an additional rider to put feet; casters mounted at one side of the foldable foothold; a fitting hole formed at the other side of the foldable foothold; and a bracket assembled to the fitting hole through a rotary shaft and attached to the side wall of the riding board, the bracket having assembly holes.

An electric scooter of standing drive has a pair of dolly wheels located behind the rear wheel to work as a parking stand. At the parked position with the handlebar stem folded, the scooter can be pulled away by hand, and vertically stand using the dolly wheels and the rear end of the deck frame to touch the ground. The scooter has a front wheel drive to assist it to start from stop, eliminating the kicking start. An electric scooter of standing-sitting drive is an improvement to the electric scooter of standing drive type. It has a seat of flat plate hinging on a pair of supporting parallel posts. The seat works as a front part of the standing deck for standing drive. When the posts rise to vertical, the seat is set for sitting drive. Its handlebar stem can be tilted and set to desired angles for comfortable driving.

An approach is provided for a foldable bike which comprises a front fork, a top tube, a down tube, a pivot hinge and the pair of auxiliary wheels. The pivot hinge is connected to the first end of the front fork, a second end of the top tube and the first end of the down tube. The first end of the top tube is pivotally connected to the pivot hinge. The first end of the top tube is pivotally connected to the pivot hinge. The auxiliary wheels mounted on the two respect sides of the rear wheel that are extended backwardly from the center of the rear wheel. The pivot hinge allows the front fork and the top tube to be folded toward the down tube. The auxiliary wheels against the ground when the the bike is folded, which is capable of standing and being pulled by a person.

A scooter has a load-carrying deck, a steering rod for steering a front wheel, two outriggers arranged on opposite sides to be pivotable between retracted stowed positions and extended support positions. Each outrigger has a wheel mounted movably on the outrigger to move between a stowed position and a ground-contacting support position. The outriggers when in their support position form a wider loading surface than the deck alone. A control arm is attached to the steering rod for movement between a folded/stowed position lying adjacent to the rod and an operating position extending forward from the steering rod. A sensor detects movement of at least a section of the control arm and, in response thereto, provides control inputs to an electric motor driving a rear wheel.

A transportation vehicle is disclosed, including front frame and rear frame. The front frame and rear frame are hinged together and the rear frame can swing left and right with respect to the front frame; the two sides of the front frame are provided with two wheel hub axles, and the driven wheels are connected to the front frame through the wheel hub axles; the rear frame is provided with a vertically configured connecting rod; the connecting rod is flexibly connected to the middle portion of the first push-pull rod, and the two ends of the first push-pull rod can swing up and down; the two ends of the first push-pull rod are respectively connected to the wheel hub axles through the rocker arm connecting rod mechanism. Through configurations of the first push-pull rod, wheel hub axles and rocker arm connecting rod mechanisms, when the transportation vehicle is making a turn, the gravity component of the human body and vehicle can offset the centrifugal force generated by the human body and vehicle. As a result, the present invention strengthens the anti-tumble capability of the transportation vehicle during turning, and enhances the stability and safety of the transportation vehicle in usage.

A bicycle includes a frame including first and second segments pivotable relative to each other between a folded position and an unfolded position. The first segment has a first face and the second segment has a second face facing the first face in the unfolded position. A hinge is disposed between the first and second faces. A locking device extends through at least one of the first and second faces.

The invention discloses a novel rapidly foldable electric vehicle comprising a main beam, a rear wheel, a cross beam, a bracket and a forward/backward movable saddle, wherein a pin is arranged at a junction between a lower end of the bracket and the main beam, a supporting post is arranged at the lower end of the bracket, the bracket and the supporting post are rotatably arranged about the pin, an included angle of less than 180 is formed between the supporting post and the bracket, and a towing wheel is arranged at a lower end of the supporting post. When the vehicle is folded, the saddle slides forward from a rear part of the cross beam and drives the bracket and the supporting post to rotate counterclockwise about the pin, the towing wheel moves downward and backward and gradually touches the ground, and after the towing wheel touches the ground, the rear wheel leaves the ground and the saddle moves to a front part of the cross beam to complete the folding action, thus the vehicle is in a towed or flat state. When the vehicle is towed, the towing wheel is positioned at a middle-rear part of a vehicle body, and when a human body stands upright, the vehicle body tilts, its center of gravity naturally shifts backward, the vehicle body has less pressure on the human body and towing is performed with less effort. When the vehicle is folded, the saddle moves forward without moving backward and the rear space of the vehicle body can be saved. When the vehicle is folded and laid flat, the towing wheel touches the ground and the vehicle body does not tip over easily.