A rotational driving force transmission mechanism includes a cylindrical shaft made of fiber reinforced plastic, and a first constant velocity joint. The shaft is joined to the first constant velocity joint via a metallic intervening member which is attached to one end of the shaft in the axial direction. The intervening member includes a shaft portion and a main body portion. The shaft portion is inserted into the one end of the shaft from a distal end side thereof. The main body portion is of a bottomed tubular shape made up from a bottom part joined to a proximal end side of the shaft portion, and a tubular portion fitted over the one end of the shaft. The first constant velocity joint includes an inner ring fitted externally over the tubular portion of the intervening member.

A shaft assembly comprises: a hollow shaft with an axis of rotation, and a hub body connected to the hub body in a force-locking manner, wherein the hollow shaft comprises, viewed in cross-section, a circumferentially closed wall with a plurality of circumferentially distributed support portions in abutting contact with the hub body and with spring portions spaced from an inner circumferential face of the hub body, wherein inner surface regions of the spring portions lie on a smaller radius around the axis of rotation than inner face regions of the support portions, wherein the wall comprises a varying thickness over the circumference, wherein the thickness in the support portions is smaller than in the spring portions.

Briefly, implementations of claimed subject matter relate to methods and devices for coupling a first rotating shaft to a second shaft. In a particular implementation, an end of a plurality of resilient fingers of a resilient structure may be radially displaced to permit positioning of the resilient structure over a first shaft. An inwardly-directed portion of each of the plurality of the resilient fingers of the resilient structure may be secured to a channel located on an inner surface of a second shaft. After securing the resilient structure to the second shaft, the one or more resilient fingers of the resilient structure may be positioned within a slotted ladder ring encircling the first shaft.

A tolerance ring includes a ring body formed of a strip plate material having a spring property and formed in a ring shape. The tolerance also has a plurality of protrusions. The protrusions are formed on the ring body and radially protrude from the ring body. An abutment joint portion is formed between a first end and a second end of the ring body in the circumferential direction. The tolerance ring includes an insertion restricting portion configured to restrict an entering amount of another tolerance ring in the axial direction being inserted into the abutment joint portion from the side of the first edge of the ring body. The insertion restricting portion is located in an area between a first axial end of the plurality of the protrusions in the axial direction and the first edge, so as to restrict the entering amount of the other tolerance ring.

A motor includes a shaft extending along a center axis, and a first groove that is recessed in a radial direction and extends in an axial direction, on an outer side surface of the shaft. The motor includes a stator core into which the shaft is inserted, and a rotation restrictor that is inserted into at least a portion of the first groove and restricts the stator core and the shaft in a circumferential direction. A carrier vehicle is equipped with the motor further including a lead wire extending from the stator. The shaft includes a shaft portion and a flange portion that overhangs to a radially outer side from one side of the shaft portion in the axial direction. The flange portion includes an opening through which the lead wire passes. The opening includes a notch connected to an outer side surface of the flange portion. The opening of the motor is positioned above the center axis.

A method of making an axle sleeve includes forming a main body comprising a cylinder and forming an expansion member whereby a diameter of the main body may be varied. The method includes cutting an inner helical cutout comprising a first slit defined through the main body and extending helically from an inner edge of the main body, cutting an outer helical cutout comprising a second slit defined through the main body and extending helically from an outer edge of the main body, forming an inner edge remaining portion comprising an annular section of the main body unbroken by the inner helical cutout, and forming an outer edge remaining portion comprising an annular section of the main body unbroken by the outer helical cutout.

In a steering system, a first universal joint includes a first yoke coupled to an intermediate shaft. A second universal joint includes a fourth yoke paired with a third yoke coupled to the intermediate shaf and a shaft attachment portion joined to the fourth yoke and in which a bolt insertion hole allowing a pinion shaft to be clamped is formed. When an angle between the intermediate shaf and a steering shaft is set to θ1, an around-axis angle of the first yoke in a rotating direction is set to ω1, and an angle between the intermediate shaft and the pinion shaft is set to θ2, a junction angle between the fourth yoke and the shaft attachment portion in the rotating direction is adjusted to set an around-axis angle of the bolt insertion hole in the rotating direction to a preset angle ω2.

A yoke assembly for receiving a shaft, the yoke assembly including a main section including a pair of planar surfaces and a shoulder portion; and a subsidiary section with a pair of planar surfaces extending between a proximal wall and a distal wall. The subsidiary section is configured and arranged to be seated and securely attached to the first main section such that the proximal wall of the subsidiary section opposes the shoulder portion of the main section, and the pair of planar surfaces of the main section oppose the pair of planar surfaces of the subsidiary section. The main section and the subsidiary section are configured and arranged to be joined together to form a receiving aperture therebetween.

A connection arrangement for axially securing a shaft-hub connection includes a shaft and a hub with an inner stop surface for the shaft and an outer groove for axially positioning a securing device. The securing device has an axially extending sleeve-shaped part and a radial collar. The sleeve-shaped part at least partly surrounds the circumference of the hub, and the radial collar at least partly engages behind the annular end surface of the hub. The inner stop surface for the shaft in the housing is formed by a recess. The securing device includes a radially deformable holding socket, the axially extending sleeve-shaped part of which is surrounded by a tensioning strap. The holding socket region which is offset radially inwards surrounds the expanded outer groove of the hub coaxially in the assembled state of the shaft-hub connection and can be locked in the expanded outer groove of the hub by the tensioning strap, the radial collar of the holding socket resting against the axial securing ring of the shaft in the locked state.

A guide member 48 includes a cylindrical portion 52 fitted to a front end of a pinion shaft 19 and extending on the side of an opposite yoke and a slit engagement plate 54 extending on the side of the pinion shaft 19 from a portion, on the side of the pinion shaft 19, of the cylindrical portion 52 and engaging with a slit 42 of a yoke 22, the cylindrical portion 52 being inserted first in a clamp portion 36 of the yoke 22 upon the yoke 22 being fitted to the pinion shaft 19, the yoke 22 being rotatably guided by the cylindrical portion 52.