A bicycle hub apparatus may comprise a wheel hub, a freewheel and a driving base. The freewheel comprises a first chainwheel and a second chainwheel, a first elastic piece, and a second elastic piece. A lateral surface of the first chainwheel comprises a first teeth while a lateral surface of the second chianwheel has a third teeth, and the first teeth is configured to engage with the third teeth to have a synchronous rotation in clockwise direction. Also, the other lateral surface of the first chainwheel has a second teeth while the other lateral surface of the second chainwheel comprises a fourth teeth such that when the first chainwheel and the second chainwheel are rolled over, the second teeth is adapted to engage with the fourth teeth to have a synchronous rotation in counterclockwise direction.

Cassette (1) for a bicycle transmission system, which comprises a first sprocket (P1) and a second sprocket (P2) smaller than the first sprocket (P1) and a support structure (S) the sprockets (P1, P2), being the inner edges (CI1, CI2) of the sprockets (P1, P2) configured by grooved surfaces (P11, P21), being the support structure (S) provided with two engagement surfaces (S1, S2) complementary of the grooved surfaces (P11, P21) of the grooved sprockets (P1, P2), such that tangential forces (T) can be transmitted between the sprockets and the support structure (S), comprising the cassette at least a spacer (E1-2, E2-3, E3-4 . . . ) between sprockets (P1, P2), wherein the base line (B2) of the second sprocket (P2) is smaller than the average diameter (D1) of the grooved surface (P11) of the first sprocket (P1), extending the spacer (E1-2) between the first sprocket (P1) and the second sprocket (P2) at least from the grooved surface (P11) of the first sprocket (P1) to at least the base line (B2) of the second sprocket (P2), such that the spacer (E1-2) allows to exert axial forces (A) on the first sprocket (P1).

A hub for bicycles including a hub shell which is rotatably supported relative to a hub axle, a rotor rotatably supported relative to the hub axle by means of two rotor bearings, and a freewheel device having two interacting freewheel components namely, a hub-side freewheel component and a rotor-side freewheel component. The two freewheel components each include axial engagement elements and they are movable relative to one another in the axial direction between a freewheel position and an intermeshing engaging position. Rolling members are provided for defined accommodation in the hub-side freewheel component to support the hub shell relative to the hub axle. An attachment portion and a centering portion are configured in the hub shell and an attachment area and a centering area are configured on the hub-side freewheel component. The attachment area is connected with the attachment portion and the centering area is centered on the centering portion.

A bicycle hub includes a housing, in which a first ratchet device, a second ratchet device, and an elastic device are received. The first ratchet device is rotated freely in the housing, and the second ratchet device is fixed to the housing. The first ratchet device has a first ratchet portion, the second ratchet device has a second ratchet portion, and the elastic device urges the first ratchet portion to engage the second ratchet portion of the second ratchet device when the first ratchet device is rotated in a direction. A driving device is connected to the first ratchet device to rotate at an end of the housing while the first and the second ratchet portions are located at an opposite end of the housing.

A bicycle hub includes a housing, in which a first ratchet device, a second ratchet device, and an elastic device are received. The first ratchet device is rotated freely in the housing, and the second ratchet device is fixed to the housing. The first ratchet device has a first ratchet portion, the second ratchet device has a second ratchet portion, and the elastic device urges the first ratchet portion to engage the second ratchet portion of the second ratchet device when the first ratchet device is rotated in a direction. A driving device is connected to the first ratchet device to rotate at an end of the housing while the first and the second ratchet portions are located at an opposite end of the housing.

A sprag clutch based freehub system that has an easily swappable free hub portion is provided. The freehub system uses a cassette driver adapter shaft (also referred herein as driver) that is positioned within the hub. The cassette driver adapter shaft (driver) and freehub body have a separable interface. This allows for easy interchanging of freehub bodies by the user while not risking contamination or damage to the hub.

Example bicycle sprocket assemblies are described herein. An example sprocket assembly includes a cassette formed by a plurality of sprockets arranged in increasing diameter order from a first end to a second end of the cassette opposite the first end. The cassette has a passageway extending between a first opening in the first end and a second opening in the second end to receive a driver hub. An outboard portion of the passageway is formed between a midpoint of the cassette and the first end of the cassette. The cassette further includes a torque transmitting profile located within the outboard portion of the passageway to interface with the driver hub. The sprocket assembly also includes a bushing to be disposed within the second opening to form a non-torque transmitting interface between the second end of the cassette and the driver hub.

Example bicycle sprocket assemblies are described herein. An example sprocket assembly includes a cassette formed by a plurality of sprockets arranged in increasing diameter order from a first end to a second end of the cassette opposite the first end. The cassette has a passageway extending between a first opening in the first end and a second opening in the second end to receive a driver hub. An outboard portion of the passageway is formed between a midpoint of the cassette and the first end of the cassette. The cassette further includes a torque transmitting profile located within the outboard portion of the passageway to interface with the driver hub. The sprocket assembly also includes a bushing to be disposed within the second opening to form a non-torque transmitting interface between the second end of the cassette and the driver hub.

A bicycle hub assembly includes a hub shell including a braking surface. A coaster brake shoe is accommodated in the hub shell and cooperates with the braking surface to generate braking force. A motor is accommodated in the hub shell and configured to be controlled for at least changing or maintaining a gear ratio.

A hub for bicycles with a hub shell rotatably supported relative to a hub axle by roller bearings and a rotor rotatably supported relative to the hub axle by at least two rotor bearings and with a freewheel device with two interacting freewheel components namely, a hub-side freewheel component and a rotor-side freewheel component. The two freewheel components are movable relative to one another in the axial direction between a freewheel position and an intermeshing engaging position in which a driving torque can be transmitted. The hub-side freewheel component is compact in configuration and a hub bearing to rotatably support the hub shell is integrated and configured therein. An outer ring of the hub bearing is configured in an axial body section of the hub-side freewheel component. A sealing unit protects the interior of the hub bearing from the entry of dirt and water.