A wiring structure of a grip heater includes an accelerator grip, a grip pulley, an accelerator position sensor configured to detect an amount of rotation of the grip pulley, and a grip heater, an engaging section that is configured to engage the grip pulley with the accelerator position sensor and transmit the amount of rotation of the grip pulley to the accelerator position sensor is installed at the grip pulley and the accelerator position sensor, a feeder cable is connected to the grip heater, and the feeder cable is wound on an outer circumference of the engaging section.

There is provided a straddle type vehicle including a processing circuit. The processing circuit is configured to: change, upon receiving a boost signal from a boost input device, a target torque from a normal torque to a boost torque obtained by adding a predetermined boost amount to the normal torque; and correct, upon receiving a predetermined inclination signal from the posture detector, the target torque such that a torque change of the drive wheel when the target torque is changed from the normal torque to the boost torque is decreased as compared with a case where the inclination signal is not received.

Various electric scooters are disclosed that include a battery receptacle configured to releasably retain a rechargeable battery therein. The electric scooter may include a deck and a strut extending between the deck and a rotatable shaft connected to a handlebar assembly. The battery receptacle may be supported by the strut, and the battery may be insertable into and removed from the battery receptacle through translation of the battery in a direction substantially parallel to a longitudinal axis of the strut. The battery may be configured for use in a power tool in addition to the electric scooter.

An operating device of a straddle type vehicle has a controller for selecting a plurality of function menus of components mounted on the straddle type vehicle. Controller supporting portions support the controller, and are disposed in the front direction of a switch box. The controller has a controller operating portion which a rider can operate. The controller operating portion is positioned in the front direction of a grip portion.

An operating device of a straddle type vehicle has a controller for selecting a plurality of function menus of components mounted on the straddle type vehicle. Controller supporting portions support the controller, and are disposed in the front direction of a switch box. The controller has a controller operating portion which a rider can operate. The controller operating portion is positioned in the front direction of a grip portion.

The embodiments herein describe a feedback system for an electric motorcycle. The feedback system notifies a user of the electric motorcycle of various conditions of the electric motorcycle via one or more output devices. In one embodiment, the feedback system causes the left and right grips of the handlebar of the electric motorcycle to vibrate to communicate information to the rider of the electric motorcycle.

A rotational torque surge brake assembly mounted to a bicycle aerobar that provides an ergonomic brake design allowing riders utilizing aerobars to brake using a natural supination motion of the forearm while remaining in the tucked, aerodynamic racing position. Braking is activated by supine radial rotation of an actuating handle grip (6) mounted rotatably about a base mounting member (7) that is itself affixed to an aerobar (9) mounted on the bicycle handlebar. The bicycle's brake cable is attached to the handle grip (6) in such a manner that radial motion of the handle (6) results in axial motion of the brake cable (10), relative to the axis of the bicycle frame.

A rotational torque surge brake assembly mounted to a bicycle aerobar that provides an ergonomic brake design allowing riders utilizing aerobars to brake using a natural supination motion of the forearm while remaining in the tucked, aerodynamic racing position. Braking is activated by supine radial rotation of an actuating handle grip (6) mounted rotatably about a base mounting member (7) that is itself affixed to an aerobar (9) mounted on the bicycle handlebar. The bicycle's brake cable is attached to the handle grip (6) in such a manner that radial motion of the handle (6) results in axial motion of the brake cable (10), relative to the axis of the bicycle frame.

An invention relates to the field of electronic vehicle control systems, in particular electric bicycles intended for heavy loads. The intelligent electronic bicycle control system includes a controller to control electric motor, a throttle handle, a sensor, a battery, a communication module for transferring data on a movement and condition of electric components and to exchange data with a mobile application and a remote control, an alarm, a light controller to control light, turns and stop signals and audio signal, a controller for collisions prevention and a bicycle computer to display the main parameters of the system, and all elements are connected by a bus. Enhanced functionality.

A personal mobility and a controlling method adjusting speed based on shape information of the handle are provided. The personal mobility includes a power device, a braking device, and a handle. The handle includes a plurality of axes provided to be movable and a deformable cover surrounding the plurality of axes. A detector detects movement of each of the plurality of axes and a controller operates the power device and the braking device based on a positional relationship between the plurality of axes according to the movement of each of the plurality of axes.