A bearing support structure wherein a shaft member that rotates about a central axis is rotatably supported by a rolling bearing split into two portions in a peripheral direction, wherein the shaft member has a fitting portion into which the rolling bearing is externally fitted, the fitting portion has a non-round shape in a direction orthogonal to the central axis, and the rolling bearing includes an inner ring that is split into two portions in a peripheral direction and is externally fitted to the fitting portion and has an inner raceway surface on an outer periphery, an outer ring that is split into two portions in a peripheral direction and is fixed radially outward of the inner ring, and that has an outer raceway surface coaxial with the inner raceway surface on an inner periphery, and a plurality of rolling elements rotatably disposed between the inner and outer raceway surfaces.

A one-way bearing, a bearing assembly, and a free-wheeling mechanism for a bicycle are disclosed herewith. The bearing assembly, comprises a one-directional bearing having an inner and outer race, a first thrust bearing and a second thrust bearing, wherein the inner and outer races of the one-directional bearing are formed to retain one or both of the thrust bearings. The one-way bearing comprises an outer race and an inner race with a one-directional bearing mechanism located between said inner and outer races, the inner race comprising an inner race ring portion, with an inner flange projecting from the inner race ring portion in a first direction parallel to an axis of rotation of the bearing, and an outer flange, projecting in a second direction away from the axis of rotation of the bearing, an outer race comprising an outer race ring portion and an outer flange portion extending axially inwardly from the outer race ring portion, there therefore being defined a first bearing surface around an outer circumference of the inner race ring portion, a second bearing surface defined by the inner circumference of the outer race ring portion, a third bearing surface defined by a first sidewall of the inner race ring portion and/or the inner flange, a fourth bearing surface defined by a second sidewall of the inner race ring portion and/or the outer flange and a fifth bearing surface defined by an inner surface of the outer race flange portion.

A spindle-shaft unit for closing a containers with a screw closure includes a spindle that is rotatable and axially movable relative to a housing and a bearing unit arranged between the housing and the spindle. The bearing unit comprises a sliding bearing that interacts with the spindle and a further bearing that interacts with the sliding bearing. The spindle is arranged at the sliding bearing such as to be displaceable and non-rotatable relative to the sliding bearing. The further bearing secures the sliding bearing so as to be rotatable and non-displaceable relative to the housing.

This bearing device 1 for a wheel is configured such that: a plurality of bolt insertion holes 2f are provided in the vehicle body mounting flange 2e of an outer member 2; knuckle bolts 34 are inserted through the bolt insertion holes 2f; a plurality of bolt press-fitting holes 3i are provided in the wheel mounting flange 3h of a hub ring 31; and hub bolts 33 are press-fitted in the bolt press-fitting holes 3i. A dam section (dam member 7) protruding radially outward is provided on the outer-side outer periphery of the outer member 2, and a cutout 7c through which a tightening tool 34T for tightening the knuckle bolts 34 inserted through the bolt insertion holes 2f is formed in the dam section (dam member 7).

The invention relates to a transmission connection mechanism of a pancake motor, which solves the technical problem that the swing of an existing pancake motor affects the motor life. The transmission connection mechanism is provided with a motor shaft, a shaft sleeve and a working shaft, wherein the shaft sleeve and the working shaft are connected by a working key, the motor shaft is provided with an internal spline, an external spline is arranged outside the shaft sleeve, the internal spline and the external spline form a spline meshing connection, and the external spline is a spherical-tooth external spline. The transmission connection mechanism of the invention can be widely applied to the transmission connection of a pancake motor.

The invention relates to an axle and bearing for a conveyor chain link, such as those used in commercial bakery equipment. The conveyor chain link generally includes at least one roller bearing wheel with a central hole, an axle pin, and a link component with a bore. The axle pin is configured to extend through the hole in the roller bearing wheel and the bore in the link component to attach the at least one roller bearing wheel to the link component. The axle pin includes a medial portion having at least one surface engagement feature configured for anti-spin engagement with the link component. The roller bearing wheel includes at least one engagement feature for anti-spin engagement with the distal end of the axle pin.

A radial support bearing assembly for use within a steering column assembly having an outer tube and a shaft, including at least one inner ring defining an inner raceway, the inner ring being axially fixed relative to the shaft, at least one outer ring defining an outer raceway, and a plurality of roller elements disposed between the at least one inner ring and the at least one outer ring in rolling contact with the inner raceway and the outer raceway. The inner ring is in direct contact with the shaft and has a circular cross-section as taken in a plane parallel to a longitudinal center axis of the shaft.

A spline-processing method is used for a wheel bearing. The wheel bearing includes outer and inner members. The inner member has formed on its inner periphery an interference-defined spline having a guide spline formed at an inboard-side end portion thereof. An intermediate component of the inner member includes a spline-formation inner peripheral surface having the interference-defined spline and the guide spline formed thereon, and a relief portion, which is formed on an outboard side with respect to the spline-formation inner peripheral surface, and has a diameter larger than that of the spline-formation inner peripheral surface. A punch used for the spline processing includes an integrated spline punch having an interference-defined spline forming surface to form the interference-defined spline, and a guide spline forming surface to form the guide spline. The integrated spline punch presses the spline-formation inner peripheral surface to form the interference-defined spline and the guide spline.

A hub bearing unit includes a radially outwardly extending flange, a first portion on a first side of the flange and a tubular portion on a second side of the flange. A bearing outer ring surrounds the first portion, and rolling elements are mounted between the first portion and the outer ring. A splined shaft of a constant velocity joint extends into the hub and has a threaded end portion inside the tubular portion. A threaded connector is mounted on the threaded end portion and has a deformable portion configured to be deformed to prevent the threaded connector from being unscrewed. A portion of the tubular portion near the flange includes a radial through hole configured to allow a torque arm of a deformation tool to access and deform the deformable portion.

The invention relates to a wheel end assembly for a vehicle, comprising a central wheel support member such as a spindle or a steering knuckle, and an outboard wheel end bearing arranged concentrically around the central wheel support member. The outboard wheel end bearing comprises roller elements accommodated between an inner race-forming part and an outer race-forming part surrounding the inner race-forming part. The inner race-forming part is configured to be supported by the central wheel support member. The central wheel support member comprises a first rotational lock portion. The inner race-forming part comprises a second rotational lock portion configured to engage with the first rotational lock portion to prevent the inner race-forming part from rotating relative to the central wheel support member. The invention also relates to a vehicle comprising such a wheel end assembly.