A vehicle includes: a vehicle body frame; a drive unit provided on the vehicle body frame and movable on a floor surface; a seat disposed above the vehicle body frame; a lift unit to raise and lower the seat between a low position and a high position; a first leg extending downward from the seat and provided with a roller at a lower end thereof; a second leg extending downward from the seat, provided with a contact member at a lower end thereof, and displaceable in an up-down direction; and a lever connected to the second leg via a transmission mechanism. When the seat is in the low position, the contact member is displaced between a use position in which the contact member contacts the floor surface and a retracted position in which the contact member is separated from the floor surface depending on a position of the lever.

A clutch locking mechanism is a clutch locking mechanism (80) mounted in a saddle type vehicle (1) and includes a clutch (26) which enters an engaged state where power can be transmitted when an actuator (28) is operated and returns to a disengaged state where power cannot be transmitted when the actuator (28) is not operated, and a locking mechanism (100) having an operator (101) which is able to bring the clutch (26) into the engaged state separately from an operation of the actuator (28).

A clutch locking mechanism is a clutch locking mechanism (80) mounted in a saddle type vehicle (1) and includes a clutch (26) which enters an engaged state where power can be transmitted when an actuator (28) is operated and returns to a disengaged state where power cannot be transmitted when the actuator (28) is not operated, and a locking mechanism (100) having an operator (101) which is able to bring the clutch (26) into the engaged state separately from an operation of the actuator (28).

A light weight, automatic release, variably adjustable bicycle stabilizer is disclosed. The invention is comprised of five main parts: a first part being an adjustable, pivoting, slightly flexible u-shaped fork that stabilizes the wheel; a second part being an anchor bracket; a third part being a down tube stabilizer; a fourth part being a compression band; and a fifth part being an onboard, LED, safety light. The invention is selectively affixed to the underside of a bicycle frame. The anchor is disposed on the down tube and the slightly flexible u-shaped fork wheel stabilizer swings out from said anchor and grabs the front wheel preventing the wheel from turning and tipping the bike over. The end of each fork is wider on the inside. This stops the bicycle from rolling backward when parked on an incline.

A light weight, automatic release, variably adjustable bicycle stabilizer is disclosed. The invention is comprised of five main parts: a first part being an adjustable, pivoting, slightly flexible u-shaped fork that stabilizes the wheel; a second part being an anchor bracket; a third part being a down tube stabilizer; a fourth part being a compression band; and a fifth part being an onboard, LED, safety light. The invention is selectively affixed to the underside of a bicycle frame. The anchor is disposed on the down tube and the slightly flexible u-shaped fork wheel stabilizer swings out from said anchor and grabs the front wheel preventing the wheel from turning and tipping the bike over. The end of each fork is wider on the inside. This stops the bicycle from rolling backward when parked on an incline.

A vehicle including a system for transferring energy between on-board vehicle components and/or between on-board and external components. The vehicle is configured to heat various components through induction to provide comfort to the rider and/or to transfer energy for charging one or more vehicle components.

A supporting frame is applied on a bicycle. The bicycle includes a main frame. In relation to the bicycle, the supporting frame has a supporting state and a folded state. The supporting frame includes a connector, a front supporting frame assembly, two connecting bars and two rear supporting frames. The connector is located on the main frame. The front supporting frame assembly includes two first pivotal connecting portions and two second pivotal connecting portions. The front supporting frame assembly is pivotally connected to the connector via the two first pivotal connecting portions. The two connecting bars both include a first connecting end and a second connecting end opposite the first connecting end. The two first connecting ends are respectively and pivotally connected to the two second pivotal connecting portions.

The present disclosure provides a method and an apparatus for processing a motor control signal, an electric vehicle, a storage medium and an electronic apparatus. The method may include: a predetermined operation is detected, wherein the predetermined operation includes that a rider leaves an electric vehicle; and a motor control signal which is input via a speed control component of the electric vehicle is shielded. Through the present disclosure, the problem that the rider of the electric vehicle forgets to press a P gear or fails to activate the P gear successfully to cause the false operation of the speed control component and thus cause a harm to the electric vehicle or a user or a surrounding environment in the related art is solved; and therefore, the vehicle is prevented from being uncontrollable, and the safety of the electric vehicle or the user or the surrounding environment is guaranteed.

A tiltable vehicle has a pair of front wheels coupled to a tiltable chassis by a tilt linkage, such that the pair of front wheels and the chassis are configured to tilt in unison with respect to a roll axis of the chassis. The tilt linkage includes a four-bar linkage having a pair of upper bar segments coupled to the chassis at spaced-apart respective inboard joints. In some examples, the inboard joints of the upper bar segments are each disposed outboard of a central chassis joint of a lower bar of the tilt linkage. An orientation sensor is configured to detect directional information regarding a net force vector applied to the chassis, and a tilt actuator operatively coupled to the chassis and configured to selectively tilt the chassis. A controller is configured to selectively control the tilt actuator based on the directional information from the orientation sensor.

An electric bicycle assembly for propelling a bicycle includes a bicycle that includes a first chain sprocket and pedals coupled to the first chain sprocket for rotating the first chain sprocket to propel the bicycle. A second chain sprocket is coupled to the first chain sprocket such that the second chain sprocket is rotated when the first chain sprocket is rotated. A generator is coupled to the bicycle and the generator is rotated to generate electrical energy when the pedals are pedaled. A motor is coupled to the bicycle and the motor is in mechanical communication with the rear wheel. The motor rotates the rear wheel when the motor is turned on for propelling the bicycle.