In a toroidal continuously variable transmission including at least one transmission unit including: an input disc and an output disc disposed coaxially; and a power roller tiltably interposed between the input disc and the output disc and configured to transmit a driving force from the input disc to the output disc, an integrally rotating member disposed so as to be spaced apart in an axial direction from at least one disc of the input disc and the output disc of each transmission unit and configured to rotate together with the at least one disc, and an annular interposed member provided between the at least one disc and the integrally rotating member and configured to rotate together with the at least one disc, are provided, and the interposed member is formed with a balance adjustment portion capable of adjusting weight balance in a circumferential direction.

A strain wave gearing has a wave generator that is provided with a rigid cam plate and a wave bearing. The wave bearing is mounted between the elliptical outer peripheral surface of the rigid cam plate and the inner peripheral surface of an externally toothed gear so as to support the rigid cam plate and the externally toothed gear in a relatively rotatable state. The wave bearing is a full complement ball bearing provided with inner and outer races which are flexible in a radial direction. Since the wave bearing is not provided with a retainer and the number of balls inserted in a ball raceway is not restricted by partition walls of such a retainer, the maximum number of balls can be mounted. Thus, the wave bearing with a large load capacity can be realized, and reliability during high-load operation of the strain wave gearing is enhanced.

In one example, a bearing or transmission has an outer race that extends circumferentially about a central axis. An inner race is disposed within the outer race and extends circumferentially about the central axis so as to be coaxial with the outer race. A plurality of load-bearing rolling elements are disposed between the inner race and the outer race, and are spaced circumferentially from one another so as to not contact one another. A plurality of separator rolling elements are disposed within the outer race. Each separator rolling element is disposed between a respective pair of the load-bearing rolling elements such that the separator rolling element is in rolling contact with the load-bearing rolling elements of the respective pair. The load-bearing and separator rolling elements form a contiguous ring.

A swivel includes an inner and an outer ring. The rings are coaxial and rotatable relative to one another around a central axis, and define a toroidal chamber and an axial seal annulus gap between the rings. The inner and outer rings are rotatably interconnected via a bearing structure. The swivel includes an upper bearing structure and a lower bearing structure on each side of the toroidal chamber. Each bearing structure interconnects the inner and outer rings. An upper and a lower sealing member is situated in the seal annulus gap near a respective upper and lower bearing structure. At least one of the inner and outer rings includes an upper member, a lower member and a central member. The upper and lower members are fixedly attached to the respective upper and lower bearing structures and the central member is independently displaceable relative to the upper and lower ring members.

A guard tube assembly for a drive shaft of a power tool has a guard tube with a tube cross section deviating from a circular shape and having an inner contour and a center. An inner support tube inside the guard tube supports the drive shaft. The inner support tube has a bearing sleeve supported by support elements on the inner contour. The inner contour has a first and a second circumferential section. The first circumferential section has a smallest spacing to the center and the second circumferential section has a largest spacing to the center. The elastic support elements have a contact surface contacting the inner contour and spaced at a contact surface spacing to the center. The contact surface spacing is longer than the smallest spacing of the first circumferential section and shorter than or identical to the largest spacing of the second circumferential section.

A bearing, including: an inner ring defining a first groove; an outer ring including a radially inner surface, the radially inner surface facing an axis of rotation of the bearing and defining a second groove and a third groove; a cage radially disposed between the inner ring and the outer ring; a plurality of balls retained by the cage, and disposed in the first groove, and in the second groove; and a preloaded resilient washer assembly including a rigid washer and a resilient washer including a radially outermost surface disposed in the third groove. The resilient washer urges the rigid washer away from the outer ring in an axial direction parallel to an axis of rotation of the bearing.

A bearing assembly includes a housing having an annular recess, an inner ring disposed within the recess and having an inner raceway, and an outer ring disposed about the inner ring and within the housing recess and having an outer raceway. At least one intermediate ring is disposed radially between the inner ring and the outer ring and has an inner intermediate raceway and an outer intermediate raceway. A first set of rolling elements is disposed between the inner ring and the at least one intermediate ring and a second set of rolling elements is disposed between the outer ring and the at least one intermediate ring. A biasing member(s) is configured to bias the inner ring or the outer ring axially toward the other one of inner ring and the bearing outer ring so as to establish a preload within the two sets of rolling elements.

A non-locating bearing assembly includes a bearing unit configured to support a rotatable component relative to a stationary component, the bearing unit including a first stationary bearing ring and a second rotatable bearing ring. The rotatable bearing ring is fixedly connectable to the rotatable component, and a bearing carrier is attached to the stationary bearing ring in a rotationally fixed but axially displaceable manner by a combination of a friction fit and an interference fit. The bearing carrier is configured to be fixedly connected to the stationary component.

A method and an apparatus for detecting wear data of a protective bearing, which relates to the technical field of a magnetic suspension bearing, and includes: firstly, a displacement of a rotor is acquired in a current falling process; then, contact time between the rotor and the protective bearing is determined according to the displacement, and a rotation speed of the rotor at any moment in the contact time is acquired, and then current wear information of the protective bearing is determined based on the displacement and the rotation speed; finally, historical wear information of the protective bearing is acquired, and the historical wear information and the current wear information are added to obtain total wear information of the protective bearing, wherein the total wear information is used for reflecting a state of the protective bearing.

A non-locating bearing assembly includes a bearing unit configured to support a rotating component relative to a stationary component, and the bearing unit includes a first stationary bearing ring and a second rotatable bearing ring that is fixedly connectable to the rotating component. The assembly also includes a bearing carrier to which the stationary bearing ring is attached in a rotationally fixed but axially displaceable manner, and the bearing carrier is configured to be fixedly connected to the stationary component.