A rear derailleur of a bicycle includes a fixing portion connected to a frame of the bicycle, a linkage assembly pivotally connected to the fixing portion, a moving portion pivotally connected to the linkage assembly, a chain guide assembly connected to the moving portion, a driving assembly, a rechargeable battery for providing an electrical energy required for the motor, a coil, and a wireless charging circuit for receiving an electric power of the coil for charging the rechargeable battery. The driving assembly includes a motor including and a driving gear assembly connected to the linkage assembly. The motor includes an output shaft for driving the driving gear assembly and for driving the linkage assembly to pivot via the driving gear assembly, thereby to drive the moving portion and the chain guide assembly to move. The coil receives an external charging power and is disposed on the fixing portion, the moving portion, or the linkage assembly.

A bicycle component controller is basically provided with a data storage device and a processor. The data storage device contains sprocket assembly information of at least one sprocket assembly. The processor is configured to perform a gear shift control based on the sprocket assembly information. The sprocket assembly information of the at least one sprocket assembly at least includes a total sprocket number and shifting gate information. The single shifting distance of the sprocket assembly information corresponds to an axial spacing between adjacent sprockets of the at least one sprocket assembly.

A bicycle component controller is basically provided with a data storage device and a processor. The data storage device contains sprocket assembly information of at least one sprocket assembly. The processor is configured to perform a gear shift control based on the sprocket assembly information. The sprocket assembly information of the at least one sprocket assembly at least includes a total sprocket number and shifting gate information. The single shifting distance of the sprocket assembly information corresponds to an axial spacing between adjacent sprockets of the at least one sprocket assembly.

A saddle-ride vehicle includes: left and right seat rails; left and right sub-frames; and a rear fender assembled from a lower side. The rear fender has a base portion and left and right vertical wall portions. The base portion forms a housing space for vehicle body components. Separation distance of the left and right vertical wall portions is smaller than separation distance of the left and right sub-frames. At upper parts of the left and right vertical wall portions each are provided with an eaves portion extending outward in a vehicle width direction to fill a gap between the vertical wall portion and the frames. The eaves portions overlap with the seat rails in an up-down direction, and the eaves portions each have a guide portion.

A bicycle part includes a housing and a lid. The housing includes an inner peripheral portion, an outer peripheral portion, an end wall portion and a connecting portion. The outer peripheral portion is spaced radially outward from the inner peripheral portion with respect to a center axis of the enclosed area. The end wall portion interconnects the inner peripheral portion and the outer peripheral portion to at least partly define an internal space. The connecting portion interconnects the inner peripheral portion and the outer peripheral portion. The lid overlies the internal space. The lid is welded to the inner peripheral portion along an inner weld path and the outer peripheral portion along an outer weld path. The lid is further welded to at least part of the connecting portion of the housing a connecting weld path connecting the inner weld path and the outer weld path.

A saddled electric vehicle (1) having a battery (100) that is attachable to and detachable from the vehicle (1) includes a vehicle electronic lock (220) which enables the vehicle (1) to be locked and unlocked, a lock control unit (320) which controls the vehicle electronic lock (220), and a sub battery (327) which supplies electric power to the lock control unit (320), in which the lock control unit (320) enables the vehicle to be unlocked in a state in which the battery (100) is removed from the vehicle (1).

A saddled electric vehicle (1) having a battery (100) that is attachable to and detachable from the vehicle (1) includes a vehicle electronic lock (220) which enables the vehicle (1) to be locked and unlocked, a lock control unit (320) which controls the vehicle electronic lock (220), and a sub battery (327) which supplies electric power to the lock control unit (320), in which the lock control unit (320) enables the vehicle to be unlocked in a state in which the battery (100) is removed from the vehicle (1).

The invention discloses a new type of bicycle capable of improving driving safety, comprising a bicycle body, assemblies of rear view mirrors are symmetrically arranged on the handlebars of the bicycle body; a brake light is arranged on the rear end of the seat of the bicycle body, turn lights are symmetrically arranged on the fixed connecting rods which connect with the frame on both sides of the seat; an illuminating light is arranged on the vertical tube of handlebar of the bicycle body, an electric horn is arranged on the upper side of the illuminating light; the application scheme is complete, simple in structure, effective in improving driving safety, and is worthy of widespread promotion.

A saddle sensor assembly is provided to a saddle or seatpost. The saddle sensor assembly includes a first part, a second part, a third part and a sensor. The first part is configured to receive a load from a rider, and moves due to the load applied by the rider. The second part is provided closer to a seatpost than the first part. The first part is movable relative to the second part between a first position and a second position. The third part supports the first part and the second part. The third part is attached to at least one of the saddle and the seatpost. The sensor is provided to one of the first part and the second part. The sensor is configured to detect relative movement of at least one of the first part and the second part between the first position and the second position.

A saddle sensor assembly is provided to a saddle or seatpost. The saddle sensor assembly includes a first part, a second part, a third part and a sensor. The first part is configured to receive a load from a rider, and moves due to the load applied by the rider. The second part is provided closer to a seatpost than the first part. The first part is movable relative to the second part between a first position and a second position. The third part supports the first part and the second part. The third part is attached to at least one of the saddle and the seatpost. The sensor is provided to one of the first part and the second part. The sensor is configured to detect relative movement of at least one of the first part and the second part between the first position and the second position.