A brake system includes a driving part driven by electric power to adjust braking force applied to a rotary body of a human-powered vehicle and an electronic controller configured to control the driving part in accordance with a rotational state of the rotary body. The electronic controller has a plurality of control modes including a first mode that drives the driving part in accordance with a user operation and a second mode that does not drive the driving part regardless of the user operation. The electronic controller is configured to switch the plurality of control modes based on setting information related to an input to the human-powered vehicle.

An omnidirectional wheel and a scooter having an omnidirectional wheel are provided. The omnidirectional wheel includes: a hub; support members, in which the support members are circumferentially distributed on the hub, each of the support members has a first mounting surface and a second mounting surface disposed oppositely, the first mounting surface is provided with a first mounting shaft, the second mounting surface is provided with a second mounting shaft, and a distance between a first axis of the first mounting shaft and a wheel center of the hub is less than a distance between a second axis of the second mounting shaft and the wheel center of the hub; first rollers, in which at least one of the first rollers is rotatably disposed on each first mounting shaft; and second rollers, in which at least one of the second rollers is rotatably disposed on each second mounting shaft.

An omnidirectional wheel and a scooter having an omnidirectional wheel are provided. The omnidirectional wheel includes: a hub; support members, in which the support members are circumferentially distributed on the hub, each of the support members has a first mounting surface and a second mounting surface disposed oppositely, the first mounting surface is provided with a first mounting shaft, the second mounting surface is provided with a second mounting shaft, and a distance between a first axis of the first mounting shaft and a wheel center of the hub is less than a distance between a second axis of the second mounting shaft and the wheel center of the hub; first rollers, in which at least one of the first rollers is rotatably disposed on each first mounting shaft; and second rollers, in which at least one of the second rollers is rotatably disposed on each second mounting shaft.

This invention relates to vehicle suspension systems and devices, and particularly to vehicle suspension systems and devices having an air spring with adjustable and/or tunable characteristics. The vehicle suspension may generally include features for modifying the spring rate of an air spring, such as, for example, to increase initial suppleness and to decrease spiking during later portions of travel. In an exemplary aspect, the fork may include features for decreasing the initial volume of the air chamber of the positive air spring during the initial part of travel and may further include features for expanding the air chamber of positive air spring during a later part of travel.

An electric mobility vehicle in a facility includes a mobility body having a wheel, a driving unit driving the wheel, and a seat for the user, and sensors, and the mobility body has a controller which controls the driving unit for at least one of automatic driving and automatic stopping by using detected data of the sensor, the controller is configured to be able to set a detection cancel area, which is an area where a part of the user can exist in front of the user, the electric mobility vehicle further includes a lower side sensor which detects an object to be avoided from under a footrest surface or from a front end portion of a footrest portion.

A foot and hand pedaled bicycle assembly that facilitates a full body working during riding includes a bicycle that has a front wheel, a rear wheel and a frame. The frame has a top member and a lower member that each pivotally extends between a seat post and a handlebar fork. The handlebar fork is urgeable toward or away from the seat post. A pair of pedals is provided and each of the pedals is rotatably coupled to the frame for rotating the rear wheel. A pair of hand cranks is provided and each of the hand cranks is coupled to the handlebar fork for steering the bicycle. Moreover, each of the hand cranks is in mechanical communication with the front wheel for rotating the front wheel when the hand cranks are cranked.

A foot and hand pedaled bicycle assembly that facilitates a full body working during riding includes a bicycle that has a front wheel, a rear wheel and a frame. The frame has a top member and a lower member that each pivotally extends between a seat post and a handlebar fork. The handlebar fork is urgeable toward or away from the seat post. A pair of pedals is provided and each of the pedals is rotatably coupled to the frame for rotating the rear wheel. A pair of hand cranks is provided and each of the hand cranks is coupled to the handlebar fork for steering the bicycle. Moreover, each of the hand cranks is in mechanical communication with the front wheel for rotating the front wheel when the hand cranks are cranked.

A performance instrument for a vehicle wherein an electronic device receives one or more operational quantities from internal sensors and/or external sensors and represents the one or more operational quantities as an analog clock face so that each clock hand is a function of one of the one or more operational quantities. The analog clock face representation provides at-a-glance apparency of the operational quantities for a user of the vehicle.

A performance instrument for a vehicle wherein an electronic device receives one or more operational quantities from internal sensors and/or external sensors and represents the one or more operational quantities as an analog clock face so that each clock hand is a function of one of the one or more operational quantities. The analog clock face representation provides at-a-glance apparency of the operational quantities for a user of the vehicle.

An omnidirectional moving device is provided with a vehicle chassis, a vehicle body, a universal coupling, and an attitude stabilizing system. In the vehicle chassis, a plurality of wheels that are capable of moving omnidirectionally are provided. The vehicle body is mounted on the vehicle chassis. The universal coupling connects the vehicle chassis to the vehicle body, and the attitude of the vehicle body relative to the vehicle chassis can be changed via this universal coupling. The attitude stabilizing system causes the vehicle chassis to move in a direction that corresponds to a change in the attitude of the vehicle body, and maintains the attitude stability of the vehicle body.