A slide actuator includes a fixed member, a movable member capable of reciprocating in a predetermined direction with respect to the fixed member, a plurality of balls interposed between the fixed member and the movable member and configured to movably support the movable member, a retainer interposed between the respective balls and configured to keep an interval between the respective balls constant and reciprocate in a predetermined stroke range, a wall portion of the fixed member provided in a moving direction of the retainer, and a retainer spring configured to couple the wall portion and the retainer. The retainer spring is disposed to suppress displacement of the retainer in the moving direction. A spring constant of the retainer spring is set to a value for causing sliding friction in the balls and pushing back the retainer in a range in which the retainer moves beyond the predetermined stroke range.

A rod bearing is mounted to a roller sliding along a rail to drive a sliding door of a vehicle body. The rod bearing includes an outer side portion formed in a ring shape and made of the same metallic material as the rail and an inner side portion made of a plastic material. The rod bearing has a hybrid type composite structure in which a material of the outer side portion and a material of the inner side portion are different from each other.

The invention relates, inter alia, to a slide bearing (10) for guiding a translationally movable sliding part, comprising a first part (11) having a first guide surface (12) suitable for interacting with a first sliding surface (67) of the sliding part, and comprising a second part (14) having a second guide surface (26) suitable for interacting with a second sliding surface (68) of the sliding part.

The special feature is that the second part (14) is movable relative to the first part (11) and is pressed by a pressure device (29) toward the first guide surface (12) such that the first guide surface (12) can be moved into contact with the first sliding surface (67) and the second guide surface (26) can be moved into contact with the second sliding surface (68).

A slide actuator includes a fixed member, a movable member capable of reciprocating in a predetermined direction with respect to the fixed member, a plurality of balls interposed between the fixed member and the movable member and configured to movably support the movable member, a retainer interposed between the respective balls and configured to keep an interval between the respective balls constant and reciprocate in a predetermined stroke range, a wall portion of the fixed member provided in a moving direction of the retainer, and a retainer spring configured to couple the wall portion and the retainer. The retainer spring is disposed to suppress displacement of the retainer in the moving direction. A spring constant of the retainer spring is set to a value for causing sliding friction in the balls and pushing back the retainer in a range in which the retainer moves beyond the predetermined stroke range.

A motion guide device is formed of: a track member including a base portion extending along a longitudinal direction, and a pair of wall portions erected from both edges of the base portion in a width direction, and having rolling element rolling grooves formed along a longitudinal direction; and a moving member which is assembled in a movable manner along the longitudinal direction between the wall portions, and to which a pair of guide members are assembled, load rolling element rolling grooves which correspond to the rolling element rolling grooves being formed in the guide members, wherein at least either one of the guide members is equipped with a biasing member on a surface of the guide member on a side opposite to a surface of the guide member on which the load rolling element rolling groove is formed.

A ball screw drive (10) including a threaded spindle (12) having a first, free end (16) and a second end (17) which can be connected to a drive, and a spindle nut (14) at least partially enclosing the threaded spindle (12) coaxially. A plurality of balls (26) recirculate in the space between the threaded spindle (12) and the spindle nut (14) form the core element. An extension sleeve (15), which connects coaxially to the spindle nut (14), is fixedly connected to the latter and moves together with it relative to the threaded spindle (12). At the first end (16) of the threaded spindle (12), a substantially circular bearing ring (18, 30, 50, 70) is attached to the outer circumference of the threaded spindle (12), which circular bearing ring serves as a shaft bearing between the threaded spindle (12) and the extension sleeve (15) and which has a noise-dampening effect due to at least one integrated spring/damping element. This spring/damping element of the bearing ring (30, 50, 70) is preferably a combination of at least one notch (32, 52, 72) on the inner circumference of the bearing ring (30, 50, 70) and an annular gap (34, 54, 74).

A slide rail includes a first rail, a second rail, a third rail, a first resilient member, a second resilient member, and a locking member. When the first rail is pulled out, the first resilient member drives the second resilient member to move along with the first resilient member to pull the second rail. When a receiving slot is aligned with a through slot, a spring piece and the locking member fall into the through slot, the spring piece separates from the first resilient member, the locking member latches onto a first step surface of the through slot to limit movement of the second rail, and the first rail continues to move.

An axially compliant rolling bearing for precision motion stages having a stage, at least one bearing member slidably disposed along a rail, and a compliant joint interconnecting the at least one roller bearing to the stage. The compliant joint is sufficiently compliant to permit movement of the stage in the axial direction while remaining stiff in other directions orthogonal to the axial direction.

To reduce the effect of a steering operation on feeling. A rack bush comprises: a bush body that is accommodated in a cylindrical housing, supports a load exerted on a rack bar while allowing the rack bar to move in the direction of an axial center O, and can be extended and retracted in a radial direction; and an elastic ring mounted on the bush body. The bush body has a mounting groove for mounting the elastic ring, the mounting groove being formed peripherally in an outer peripheral surface, and the mounting groove having a large-diameter part where the circumferential radius of a groove bottom is a first radius r1, and a small-diameter part where said radius is a second radius r2 that is less than the first radius r1. This configuration allows the formation of an elastic ring protruding part, in which the elastic ring protrudes greatly from the outer peripheral surface of the bush body, and an elastic ring embedded part, in which the elastic ring is embedded in the outer peripheral surface of the bush body.

A steering column assembly for a vehicle may include a buffer structure provided between a steering housing and a steering shaft inserted into the steering housing to distribute vibration applied thereto and to compensate for the distortion of the steering shaft and a clearance of the steering shaft with the steering housing, wherein a support structure is also provided to secure the support performance of the steering housing with respect to a mounting bracket in the event of a tilt and a longitudinal motion of the steering housing, ensuring the horizontal rigidity of the steering housing and reducing vibration applied thereto.