A footrest assembly for mounting to a vehicle rail. A position of the assembly along the rail is adjustable. A footrest is connected to a rail mount to be pivotable about a footrest pivot axis between an adjustment position allowing adjustment of the assembly along the rail and a locked position. A clamping member, movable by the footrest relative to the rail mount, is in a releasing position when the footrest is in the adjustment position and in a clamping position when the footrest is in the locked position. When the clamping member is in the clamping position and the assembly is mounted to the rail, a portion of the clamping member and a portion of the rail mount are disposed on opposite sides of the rail and the clamping member applies a clamping pressure to the rail. The locked position sets the position of the assembly along the rail.

A transmission for a saddled vehicle with which a posture of a rider is easily held during driving of the vehicle and a speed change detection device can be protected. A step for the driver extends outward in a vehicle width direction from a lower frame; a gear change pedal is turn-operated by a rider's foot for speed change; and a link for detection is coupled with the gear change pedal. A speed change detection device is coupled with a tip of the link for detection, and detects a speed change operation by the gear change pedal. The gear change pedal is arranged on an outer side of a lower frame in the vehicle width direction, and the speed change detection device is arranged on an inner side of pivot frames and the lower frame in the vehicle width direction.

A transmission for a saddled vehicle with which a posture of a rider is easily held during driving of the vehicle and a speed change detection device can be protected. A step for the driver extends outward in a vehicle width direction from a lower frame; a gear change pedal is turn-operated by a rider's foot for speed change; and a link for detection is coupled with the gear change pedal. A speed change detection device is coupled with a tip of the link for detection, and detects a speed change operation by the gear change pedal. The gear change pedal is arranged on an outer side of a lower frame in the vehicle width direction, and the speed change detection device is arranged on an inner side of pivot frames and the lower frame in the vehicle width direction.

A ride-on toy with electronic speed controller for superior user experience is described herein. A ride-on toy as described herein may be in the form of a ride-on toy car, truck, jeep, motorcycle or the like and may be used with up to a 24-volt power source as opposed to a 12-volt power source as is common in the art. An electronic speed controller of the present disclosure provides variable speed control to at least one and preferably at least two motors from separate accelerator and brake mechanisms such as pedals. Conventional ride-on toys such as those described herein typically contain a single-pole switch such as pedal that provides all-or-nothing power to a motor as opposed to modulation of two motors by two actuation means. A ride-on toy as described herein may combine various controller components in unique ways to achieve the superior results as described herein.

A ride-on toy with electronic speed controller for superior user experience is described herein. A ride-on toy as described herein may be in the form of a ride-on toy car, truck, jeep, motorcycle or the like and may be used with up to a 24-volt power source as opposed to a 12-volt power source as is common in the art. An electronic speed controller of the present disclosure provides variable speed control to at least one and preferably at least two motors from separate accelerator and brake mechanisms such as pedals. Conventional ride-on toys such as those described herein typically contain a single-pole switch such as pedal that provides all-or-nothing power to a motor as opposed to modulation of two motors by two actuation means. A ride-on toy as described herein may combine various controller components in unique ways to achieve the superior results as described herein.

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.

A longitudinal two-wheel somatosensory car, comprising a car frame, and a front wheel and a rear wheel that are provided at the front and rear ends of the car frame. The rear wheel is connected to a drive motor which is used for driving the rear wheel. The two-wheel car further comprises a somatosensory platform. The somatosensory platform is built-in with an attitude sensor. The somatosensory platform in a mechanical transmission connection with the motor stator shaft of the drive motor. The traditional balanced structure, in which the wheels are provided on the left and right sides of a balanced car, is changed to a structure in which the moving wheels are provided at the front and the rear ends.

The application relates to a pedal mechanism and a housing of a balancing vehicle. The pedal mechanism comprises a pedal body, and an internal framework is arranged inside the pedal body. A lower side of the pedal body is also formed with an induction probe for inducting a control system inside a balancing vehicle. A housing of the balancing vehicle comprises a pair of symmetrically arranged and relatively rotatable inner housings, the inner housings are connected with the upper housing, and the pedal mechanism installed at upper housing. The pedal body and the induction probe are integrally molded, which has the advantages of less multiple assembly processes, shorter processing time, higher precision, and not easy to fall off which strengthens the stability of the structure.

The application relates to a pedal mechanism and a housing of a balancing vehicle. The pedal mechanism comprises a pedal body, and an internal framework is arranged inside the pedal body. A lower side of the pedal body is also formed with an induction probe for inducting a control system inside a balancing vehicle. A housing of the balancing vehicle comprises a pair of symmetrically arranged and relatively rotatable inner housings, the inner housings are connected with the upper housing, and the pedal mechanism installed at upper housing. The pedal body and the induction probe are integrally molded, which has the advantages of less multiple assembly processes, shorter processing time, higher precision, and not easy to fall off which strengthens the stability of the structure.

A device for a gear shift system for a vehicle, the gear shift system comprising a gear shift member, the device comprises a device member, and a member connector configured to connect to the gear shift member and thereby connect the device to the gear shift system so that, in use, one of the device member and the gear shift member is beneath a rider's foot to provide a first member, and the other of the device member and the gear shift member is above the rider's foot to provide a second member, wherein in use downwards movement of the first member effects a first gear shift and in use upwards movement of the second member effects a second gear shift.