A vehicle having an electrical drive wheel hub system (30) and the hub system incorporated in the vehicle has a wheel hub (18) driven by an electric motor (31) formed by a brushless DC motor having stators (40) and rotors (42). The electric motor is arranged to drive an epicyclic gear system (32) which provides a reduction gear arrangement to drive the hub (18). Located entirely within the periphery of the stator is power circuitry and control circuitry for the electric motor, the circuitry being provided on toroidal printed circuit boards (70, 71).

A network-enabled bicycle comprising a bicycle frame and an electronic device mounted to said bicycle frame is provide. The electronic device of network-enabled bicycle is configured to communicating with other network-enabled bicycles and/or a server via a wireless network access point. In general, a set of network-enabled bicycles are equipped with respective electronic devices which are programmed for allowing the bicycles in the set of bicycles to exchange data directly or indirectly with each other and/or exchange data directly or indirectly with the server via one or more of the wireless network access points connected to the server through a data network. In accordance with one specific example of implementation, the network-enabled bicycle connects to the wireless network access point over an open Wi-Fi connection.

A central shaft torque sensing system for an electric bicycle having a centre-mounted motor. The system comprises a central shaft, a centre-mounted motor and a controller, and also comprises a torque sensor and a strain sleeve. The controller is respectively connected to the torque sensor and the centre-mounted motor, and the motor comprises a main housing, a coil stator, a rotor, a motor output gear shaft, a planetary reduction mechanism and a dual-ratchet clutch, one end of the strain sleeve being connected to the dual-ratchet clutch, the other end being sleeved on the central shaft and fixedly connected thereto, the torque sensor being mounted on the sleeve. The motor output gear shaft is sleeved on the central shaft and forms an integrated structure with the rotor of the motor, the coil stator is fixed on the main housing, the rotor is wrapped on the outside of the coil stator and fixedly connected to the motor output gear shaft, the planetary reduction mechanism is arranged within the main housing, and the gear shaft engages with the planetary reduction mechanism via a gear. The present motor driving system provides corresponding assistance according to the specific requirements of a rider.

A central shaft torque sensing system for an electric bicycle having a centre-mounted motor. The system comprises a central shaft, a centre-mounted motor and a controller, and also comprises a torque sensor and a strain sleeve. The controller is respectively connected to the torque sensor and the centre-mounted motor, and the motor comprises a main housing, a coil stator, a rotor, a motor output gear shaft, a planetary reduction mechanism and a dual-ratchet clutch, one end of the strain sleeve being connected to the dual-ratchet clutch, the other end being sleeved on the central shaft and fixedly connected thereto, the torque sensor being mounted on the sleeve. The motor output gear shaft is sleeved on the central shaft and forms an integrated structure with the rotor of the motor, the coil stator is fixed on the main housing, the rotor is wrapped on the outside of the coil stator and fixedly connected to the motor output gear shaft, the planetary reduction mechanism is arranged within the main housing, and the gear shaft engages with the planetary reduction mechanism via a gear. The present motor driving system provides corresponding assistance according to the specific requirements of a rider.

A number of variations may include a product that may include a hub. A linked element may be connected with the hub to provide at least one of an input or an output from the hub. The hub may include a shell, a shaft may extend through the shell, and a gear set may be disposed in the shell. The linked element may be connected to the gear set through a rotatable element. A rotatable component may be connected with the gear set. The rotatable element may be engageable with the rotatable component through the gear set. An engagement mechanism may engage and may disengage the gear set from at least one of the shaft or the shell.

A number of variations may include a product that may include a hub. A linked element may be connected with the hub to provide at least one of an input or an output from the hub. The hub may include a shell, a shaft may extend through the shell, and a gear set may be disposed in the shell. The linked element may be connected to the gear set through a rotatable element. A rotatable component may be connected with the gear set. The rotatable element may be engageable with the rotatable component through the gear set. An engagement mechanism may engage and may disengage the gear set from at least one of the shaft or the shell.

A bicycle gearing system includes input and output shafts, two planetary gear systems, and a clutch mechanism. The clutch mechanism includes three clutch presser plates for frictional engagement with two clutch disks and a clutch base. A motor rotates a camshaft formed with cams selectively engageable with cam followers for driving the clutch presser plates to rotate. Steels balls are provided within cavities formed between the clutch presser plates and a clutch housing to convert rotation of clutch presser plates to linear force for frictional engagement with the two clutch disks and the clutch base. Different angles of rotation of the camshaft produce different clutch and gear combinations and different gear ratios.

A bicycle image capturing device is provided that reduces annoying operations for changing an operation state. The bicycle image capturing device includes a controller. The controller includes a reception unit and an electronic control unit. The reception unit is configured to obtain information related to a component of a bicycle. The bicycle component is operable in at least a first state and a second state that differs from the first state. The electronic control unit is configured to control a first image capturing unit based on the information obtained by the reception unit.

A bicycle transmission includes an axle, an input component, a power transmission mechanism, a shift mechanism and an output component. The input component receives manually applied rotational force. The output component is rotatably supported by the axle. The power transmission mechanism transmits the rotational force of the input component to the output component through one of a plurality of power transmission paths. The shift mechanism includes a shift input member, a shift control member, a first saver spring and a second saver spring. The shift input member is settable in a plurality of rotational positions. The shift control member rotates in conjunction with movement of the shift input member to select one of the power transmission paths. In the shift mechanism, as the shift input member rotates in the first direction, the shift control member receives the rotational force applied in a first direction through the first saver spring.

A multi-speed hub gear, comprising: an axle adapted to be fixed against rotation; a hub shell; a plurality of planetary gear sets, each comprising: a central gear concentrically fixed on the axle, a rotating gear carrier mounting at least one rotating gear to revolve around the center of the central gear; and a ring gear rotated by the at least one rotating gear; wherein a respective the ring gear of one of the sets is mechanically connected to a respective the rotating gear carrier of another of the sets such that the sets rotate in conjunction; and a gear shifter adapted to engage at least one of the sets to the hub shell while disengaging another of the sets from the hub shell.