A clutch assembly is disclosed. The clutch assembly includes a rotational component including a hub configured to rotate relative to a mounted component; and a clutch configured to selectively transmit rotational input from the mounted component to the hub. The clutch includes a first ring including a first surface; a second ring including a second surface; a cage defining a plurality of pockets which are bounded by the first surface and the second surface; and a plurality of rollers each positioned in a respective one of the plurality of pockets. The first ring includes a pair of ramps in each pocket. The second ring rotates relative to the first ring when the plurality of rollers are in a neutral position between the pair of ramps, and the second ring rotates with the first ring when the plurality of rollers are positioned on either of the ramps.

A decoupler assembly comprises a torque equalizer and a one-way clutch bearing. The torque equalizer comprises an inner member having a rotational axis, an outer member disposed concentrically and surrounding the inner member, and two arcuate spring elements arranged between the inner member and the outer member, and configured to transmit torque between the inner and outer members. The inner member is rotationally displaceable relative to the outer member at least 30 degrees upon compression of the two arcuate spring elements. The one-way clutch bearing is located in the same radial plane as torque equalizer and rotationally connected to the inner member or the outer member. The one-way clutch bearing comprises an outer race, an inner race, and a plurality of individual wedging locking elements that are disposed between the inner and outer races. The decoupler assembly may comprise a single spiral spring element or a rubber-based spring element.

A return stop includes a rotational inner ring, a stationary, fixed outer ring, and a cage mounted radially between the inner ring and outer ring. The cage has at least two pairs of rollers each having a first and a second roller. A clamping rail is formed on an outer peripheral surface of the inner ring for each roller. A radial recess is formed on the inner ring in the peripheral direction directly adjacent to the respective clamping rail. Also, both of the clamping rails of the roller pairs are formed in the peripheral direction in opposite directions away from each other. In a free-running operation of the return stop, only one roller of each pair of rollers comes into position on the inner ring and the outer ring. The other roller of each pair of rollers does not come into position at least one the inner ring.

The present invention relates to a coupling arrangement for a driving device, wherein the coupling arrangement comprises an input, an output and a coupling, wherein the coupling is non-rotatably connected with the input or with the output, wherein the coupling furthermore comprises torque transmission means which in the coupled condition are configured to connect the output with the input for transmitting a torque from the input to the output, wherein upon exceedance of a torque threshold value in a first operating condition the torque transmission means are arranged such that the input is periodically separated from and connected with the output, and that when the torque threshold value is not reached in a second operating condition, the torque transmission means are arranged such that the input is permanently connected with the output for transmitting a torque.

A one-way clutch apparatus of torque input-switching type in which torque capacity can be secured without increasing an axial dimension. The one-way clutch apparatus of drive input-switching type, includes a plurality of first torque transmitting members interposed between a shaft 3 and an intermediate ring 7 at circumferential predetermined intervals, and provided for transmitting torque between the shaft 3 and the intermediate ring 7, and a plurality of second torque transmitting members interposed between the intermediate ring 7 and an outer ring 5 at circumferential predetermined intervals, and provided for transmitting torque between the intermediate ring 7 and the outer ring 5, in which either the torque input into the shaft 3 or the torque input into the outer ring 5 is transmitted to the intermediate ring 7, in which the first torque transmitting member is a sprag 23 and the second torque transmitting member is a roller 29.

A spring component for a ratcheting mechanism, such as a ratchet wrench. The spring component is shaped to be retained in a recess without any special machining. For example, the spring component can be retained at three abutment points. A leaf of the spring component can abut a pawl, and a base portion opposite the leaf can abut the drive gear. Support arms can abut the sidewall of the recess to retain the spring component within the recess without the need for special machining or tooling.

A return stop selectively locks a rotatable inner ring to a stationary outer ring. A cage supports at least two roller pairs, each of which consists of two rollers, wherein a spring element spring-loads the two rollers against the outer ring. Each spring element is a double spring having two spring sections and a connecting section connecting the two spring sections to each other and to the cage. In response to rotation of the cage relative to the inner ring, one roller of each roller pair comes to bear against a ramp of the inner ring and the outer ring. The cage has a driver element at one end face which protrudes axially into the inner ring and can be connected to a contoured section on the inner ring in order to produce positive-locking attachment.

A drive assembly including a wedge clutch assembly is disclosed. The wedge clutch assembly includes a first cage having a first plurality of tapered crossbars that at least partially define a plurality of tapered wedge pockets. A plurality of wedges are each arranged within a respective one of the plurality of wedge pockets and within a circumferential groove of one of an outer ring or an inner ring. The plurality of wedges each including a ramped surface facing a corresponding one of a plurality of ramps defined in the outer ring or inner ring. Movement of the first plurality of tapered crossbars in a first axial direction or a second axial direction circumferentially drives the plurality of wedges into contact with the circumferential groove such that an input drive gear drives an output.

A linear clutch includes a main body engaged with a locking assembly. The locking assembly includes a spring and a wedge configured to engage the spring. The wedge includes a first surface and a second surface opposite the first surface, with the second surface including a taper configured to engage a taper on a wall section of the main body. The locking assembly also includes a roller bearing assembly configured to fit within the tapers of the first wedge and the main body. Furthermore, the locking assembly includes a lever configured to engage the wedge and to move between an unlocked position and a locked position.

To provide a cam clutch that allows use of the outer race as a rotating member without requiring a complex structure, and that allows a size reduction in the axial direction. The cam clutch includes an operating mode switch mechanism (140) for switching between two or more of a free state that allows relative rotation in both directions, a one-way clutch mode that allows relative rotation in one of forward and reverse directions, and a locked state that prohibits relative rotation in both directions. The operating mode switch mechanism (140) includes a cam orientation changing part (141) axially movable independently of rotation of the inner race (110) and the outer race (120). A plurality of cams (131) include an engaging portion (136) protruding from a side face toward the cam orientation changing part (141).