A wedge clutch, including: outer and inner races; a wedge plate radially between the inner and outer races; and an electromagnetic actuator. The electromagnetic actuator includes: a coil; a first coil core piece including a first end disposed within the coil and a second end connected to the wedge plate; and a second coil core piece including a first end disposed within the first coil and a second end connected to the wedge plate. In a locked mode of the clutch, the inner race and outer races and the wedge plate are non-rotatably connected for rotation of the inner race in a circumferential direction. In a free-wheel mode of the clutch, the inner race is rotatable, with respect to the outer race, in the circumferential direction. To transition from the locked mode to the free-wheel mode, the electromagnetic actuator is arranged to be energized to radially contract the wedge plate.

The enclosed invention is a new one way clutch where linear or rotary motion between two bodies is transmitted in only one direction by one or more links moving in one of the bodies and connected with the other by friction or positive engagement, the link(s) plays the role of a follower to the cam surface on the other body. The link(s) could be rigid or flexible or in combination of both, and its contact is insured by springs which could be separate or part of any of the mechanism bodies. The link(s) causes the two bodies to cease and move together in the driving direction, and to release in the opposite free movement direction. One of the two bodies can be omitted and replaced by a part of the using machine. Links and cam lubes could be used in pairs. If links reset is needed, flexible elements or additional cam-follower mechanism can be used to avoid impact. Higher forces and torques can be transmitted with minimum backlash, surface fatigue and maximum indexing rate and service life.

A clutch apparatus comprises a first race, a second race arranged coaxial with and rotatable relative to the first race, and an engagement mechanism provided between the first race and the second race for engagement of the first race and said second race. The engagement mechanism comprising a first clutch allowing rotation of the first race in only one direction, and a second clutch arranged axially adjacent to the first clutch, the second clutch comprising a rotary member that is provided on the second race in a rotatable and axially immovable manner and a movable member that is movable in the axial direction, and a cam mechanism disposed between the rotary member and the movable member, and the movable member being engaged with the first race by being moved in the axial direction by the cam mechanism.

A non-return device for coaxial rotation transmission includes coaxial input and output shafts, a frame for guiding the rotation of the shafts. A locking element is urged in radial translation through a channel of the output shaft between a radial locking position, in which the locking element projects from the channel so as to prevent a rotation of the output shaft by abutting against the frame, and a radial unlocking position, in which the locking element is retracted so as to allow axial rotation of the output shaft. The input shaft includes means for radially switching the locking element between the locking and unlocking positions thereof.

A bicycle crank transmission apparatus includes: a hollow shaft member; a base plate coupled to the shaft member on one side and installed securely on a bottom bracket featuring a spindle on the other side; a chainring housing coupled to the shaft member in a way that allows its rotation and having a ring gear installed securely inside; a reduction gear unit arranged in the middle of the ring gear; a directly-coupled ratchet unit installed on the ring gear; a crank cover where a coupling shaft coupled to the spindle is perpendicularly provided in the center and where clutch ratchet teeth, which are engaged with the directly-coupled ratchet unit, and directly-coupled ratchet teeth are vertically stacked on the internal wall surface; and a sun gear installed on the coupling shaft in such a way that it only rotates in clockwise direction and partially engaged with the reduction gear unit.

A clutch includes a rotatable inputting member, a rotatable outputting member, a stationary member, and a contact member. The outputting member includes an output contact portion. The contact member is positioned between the outputting member and the stationary member and includes an arcuate first contact surface and a second contact surface. When the input torque for rotating the inputting member is inputted, the outputting member and the contact member rotate in contact with the inputting member. When a reverse input torque for rotating the outputting member is inputted, the outputting member is spaced from the inputting member, and the output contact portion of the outputting member urges the first contact surface against the stationary member by urging the second contact surface of the contact member thereby to prevent rotation of the outputting member.

A clutch assembly comprises a cylindrical driving member, a cylindrical driven member, coaxial with the cylindrical driving member, and a clutch cylinder between the driving member and the driven member and coaxial with the driving member and the driven member. The clutch assembly further includes a spring biasing the clutch cylinder towards the clutch cylinder. The clutch assembly also includes a plurality of friction pads, each one being attached to a different one of movable portions, and acting in response to movement of its movable portion, to cause frictional engagement between the driving member and the driven member, so that the driving member rotates the driven member. The clutch assembly also includes a U-shaped spring located in a slot in the driving member and compressible between the driving member and the clutch cylinder for rotationally biasing the clutch cylinder relative to the driving member in a clutch engagement direction.