Overrunning clutch units are disclosed. In one example, the overrunning clutch unit may include inner and outer rings that can be rotated relative to each other. Clamping members may transmit a torque between the two rings in one peripheral direction, the clamping members being arranged between the rings. A first bearing device may be configured to support the two rings, wherein the first bearing device is arranged between the rings at a first axial side of the clamping members. A second bearing device may be configured to support the two rings, wherein the second bearing device is arranged at a second, opposing, axial side of the clamping members so that a tilting of the inner ring relative to the outer ring is prevented.

A power lock actuator is provided for a door lock mechanism of a vehicle. The actuator includes an electric motor, a linear drive, and a slip clutch between the motor and the linear drive. The clutch includes a dual-lobe pinion for pulsed energy transmission from the motor to the linear drive, to provide soft starts and stops, which extend the life of the drive assembly 26. The linear drive includes a screw with multiple, discontinuous male thread segments to minimize friction with female threads on the extendible and retractable carriage, thereby minimizing wear between the screw and the carriage.

A power lock actuator is provided for a door lock mechanism of a vehicle. The actuator includes an electric motor, a linear drive, and a slip clutch between the motor and the linear drive. The clutch includes a dual-lobe pinion for pulsed energy transmission from the motor to the linear drive, to provide soft starts and stops, which extend the life of the drive assembly 26. The linear drive includes a screw with multiple, discontinuous male thread segments to minimize friction with female threads on the extendible and retractable carriage, thereby minimizing wear between the screw and the carriage.

A clutch assembly to adapt a clutch for use with a mud motor and a power take off (PTO) assembly is provided. The motor includes a body and a driving shaft, wherein the PTO assembly includes a PTO housing and a driven shaft. The clutch assembly includes a centrifugal clutch and a clutch housing. The clutch includes a hub that engages with the driving shaft, a shoe containing a plurality of fly-weights and an elastic member, and an outer drum casing adapted to selectively engage with the plurality of fly-weights when the rotational speed of the driving shaft is above a predetermined threshold. The clutch housing surrounds the centrifugal clutch and allows the clutch to be installed between the body of the motor and the PTO housing. The outer drum casing has a shaft fixed thereto that is adapted to engage with the driven shaft of the PTO assembly.

A clutch assembly to adapt a clutch for use with a mud motor and a power take off (PTO) assembly is provided. The motor includes a body and a driving shaft, wherein the PTO assembly includes a PTO housing and a driven shaft. The clutch assembly includes a centrifugal clutch and a clutch housing. The clutch includes a hub that engages with the driving shaft, a shoe containing a plurality of fly-weights and an elastic member, and an outer drum casing adapted to selectively engage with the plurality of fly-weights when the rotational speed of the driving shaft is above a predetermined threshold. The clutch housing surrounds the centrifugal clutch and allows the clutch to be installed between the body of the motor and the PTO housing. The outer drum casing has a shaft fixed thereto that is adapted to engage with the driven shaft of the PTO assembly.

A centrifugal clutch is disclosed. The clutch may include an inner rotating element whose outer periphery includes a plurality of ramps and at least one centrifugal weight device surrounding the inner rotating element, which includes a plurality of peripherally distributed centrifugal weights and whose inner periphery includes a plurality of counter ramps for forming a positive frictional engagement with the ramps of the inner rotating element. It may further include an outer rotating element surrounding the at least one centrifugal weight device, wherein the centrifugal weights can be pressed outwards through a friction lining against an inner periphery of the outer rotating element in opposition to the action of a spring arrangement. The centrifugal weight device may be generally formed by an annular plate structure including at least one plate element, wherein the plate structure includes a plurality of peripherally distributed peripheral sections that form the centrifugal weights.

A centrifugal clutch is disclosed. The clutch may include an inner rotating element whose outer periphery includes a plurality of ramps and at least one centrifugal weight device surrounding the inner rotating element, which includes a plurality of peripherally distributed centrifugal weights and whose inner periphery includes a plurality of counter ramps for forming a positive frictional engagement with the ramps of the inner rotating element. It may further include an outer rotating element surrounding the at least one centrifugal weight device, wherein the centrifugal weights can be pressed outwards through a friction lining against an inner periphery of the outer rotating element in opposition to the action of a spring arrangement. The centrifugal weight device may be generally formed by an annular plate structure including at least one plate element, wherein the plate structure includes a plurality of peripherally distributed peripheral sections that form the centrifugal weights.

A garden tool power system comprises a motor, a reducer and a transmission shaft. The motor transmits the power to the transmission shaft through the reducer to drive wheels of the transmission shaft to rotate. The reducer comprises a pinion connected to an output end of the motor and a gear engaged with the pinion. The transmission shaft includes left and right shafts connected with each other through a connecting shaft. The gear mounted on the connecting shaft has at least two guiding rods transversely located thereon and two centrifugal blocks located between the guiding rods. Each guiding rod has a spring surrounded therearound and each spring located between two centrifugal blocks has two opposite ends respectively abutted against the corresponding portion of the centrifugal blocks. A fixing sleeve provided on the periphery of the centrifugal blocks is mounted on the transmission shaft and has buckle structures matching with the centrifugal blocks.

A device has a ceiling unit provided with a cap which when moving to an open position, lowers a guide under the influence of the force of gravity to an obliquely downwardly directed position. In this position, under the influence of the force of gravity or by means of a gas spring, an arm 15 slides along the guide and via a window to the outside. On the end of the arm there is a cable guide 19 over which a descending cable 21 is turned.

Descending units 27 are present on the descending cable. Each descending unit has a cable wheel 37 around which the descending cable is turned. The cable wheel is connected to the housing of the descending unit via a centrifugal brake. This centrifugal brake ensures that the speed of rotation of the cable wheel and therefore the descent speed is not too high.

Furthermore, the descending unit has a further centrifugal brake which ensures additional braking in case the descent speed exceeds a certain limit.

A rotor assembly includes a rotor plate, a friction shoe slidably coupled to the rotor plate and configured to move in a radial direction, and a biasing mechanism operably coupled to the friction shoe and configured to force the friction shoe in a radially inward direction. A predetermined rotation of the rotor plate imparts a centrifugal force on the friction shoe sufficient to overcome the biasing force of the biasing mechanism such that the friction shoe moves in a radially outward direction.