A mirror device includes: a mirror having a rotation shaft and a reflecting surface that reflects display light; a support portion having a cylindrical shape, having a base end fixed and a tip end being a free end, and configured to rotatably support the rotation shaft; and a motor that pivots the mirror, in which the rotation shaft is inserted into the support portion while spreading the support portion outward in a radial direction, and is slidably supported by the support portion.

This invention relates to a drive system for an automatic step. Some embodiments include a rotary actuator for moving an automatic step, a crank arm pivotally coupled to the actuator and pivotable about a central shaft, and a first link pivotally coupled to the crank arm, the first link having first and second ends. The system has one or more force mitigation mechanisms capable of reducing forces eccentric with respect to the actuator. A first force mitigation mechanism engages when the step is deployed or nearly deployed by aligning the central shaft with the first and second ends of the first link along a first axis to generally place eccentric forces originating from the step against the central shaft of the crank arm instead of directly engaging the actuator. A second force mitigation mechanism allows the crank arm to yield without forcing the actuator by using a clutch adjacent to the central shaft.

An electric motor has a stator and a rotor which is arranged on a motor shaft in a rotationally fixed manner. The motor shaft is rotatably mounted about a rotational axis in at least one rolling bearing within a motor housing. The rolling bearing is arranged in a bearing shield in a bearing receiving area, the outer ring of the rolling bearing is pretensioned by a spring disc which sits in the bearing receiving area in a fixed manner to the housing, and the spring disc has an opening and a number of spring elements raised axially towards the outer ring in a disc body surrounding the opening.

Systems, apparatuses, and methods of a variable position ball joint with dynamic length are disclosed and include a ball, and a seat with a guide surface; an arc of the ball defines endpoints of an arc path for revolving the ball in the guide surface; a center point of the ball is concentric with a center of rotation of the seat so that the center point of the ball and the seat move in a single axis of movement; and an interface that guides the ball along the guide surface, wherein the guide surface is parallel to the single axis of movement to cause the ball to traverse the seat travel arc while maintaining a center of rotation concentric with the seat resulting in a change in length of an attached component with respect to a concentric center point of rotation during an articulation action of the ball joint.

A motor adjustment drive for a vehicle steering column includes a threaded spindle with an axis. The threaded spindle engages a spindle nut. A drive unit and a gear wheel which is connected to the spindle nut or the threaded spindle for rotation therewith is driveable to rotate by the drive unit and is rotatably mounted in a bearing housing between two outer bearing rings that are axially supported at the bearing housing. The outer bearing rings each have, on their sides facing one another, a circumferential outer bearing face that is coaxial to the axis. Each outer bearing face lays opposite a bearing face embodied on the end side at the gear wheel. An outer bearing ring is axially resiliently supported at the bearing housing via an elastic element, which exerts an axial force that biases the two outer bearing rings toward each other.

Provided is a rotation member connecting structure that does not require an operation of connecting a rotation support member and the rotation member to each other and can prevent rattling of the rotation member with respect to a rotation member support member. In the rotation member connecting structure, a rotation support member 10 has a support shaft 20, and a rotation member 30 has a retention part 50. The support shaft 20 has a restriction part 25 that restricts axial movement of the support shaft 20 with respect to the retention part 50 and a sliding part 27 that slides over an inner periphery of the retention part. The rotation support member 10 and the rotation member 30 are made of materials that are not bonded to each other during molding by the resin materials. In the inner periphery of the retention part 50,a portion that closely contacts the sliding part 27 is formed to be continuous in a circumferential direction so that the rotation support member 10 and the rotation member 30 are molded in a connected state.

A coupling mechanism includes a cable including a cable end at an end portion, a slider including a coupling part coupled with the end portion, and a joint case including a slider housing space, wherein the coupling part includes a cable end housing part, and a separation restraining part restraining cable separation from the slider, and wherein the separation restraining part includes an installation space where the cable extended from the cable end is disposed with the cable coupled with the slider, an inlet opening in a direction perpendicular to a cable axis and allowing the cable to move in the direction and pass through the inlet, a passage part allowing the cable to move to the installation space through the inlet, and a first restriction part blocking a cable movement direction when the cable in the installation space moves in a direction parallel to a passage part's extending direction.

A shaft-bearing bush assembly for a valve arrangement for an air-conditioning system is disclosed. The shaft-bearing bush assembly includes a shaft drive-connectable to a valve of the valve arrangement and a bearing bush, in which the shaft is rotatably received relative to the bearing bush between a first rotary position and a second rotary position about an axis of rotation extending along the axial direction. A bush projection is non-rotatably arranged on the bearing bush relative to the bearing bush and a shaft projection is non-rotatably arranged on the shaft relative to the shaft. The bush projection and the shaft projection are matched to one another such that the bush projection provides a rotary stop for the shaft projection for limiting the rotary movement of the shaft between the first rotary position and the second rotary position.

An object of the present invention is to provide a steering apparatus capable of improving a function of a bearing that supports a steering shaft. A steering apparatus includes a steering shaft, a first housing member, a second housing member, and a bearing. The steering shaft rotates according to a rotation of a steering wheel. The first housing member is located on one side in a rotational axial direction of the steering shaft, and includes a cylindrical portion and a flange portion. The cylindrical portion surrounds the steering shaft. The flange portion extends in a radial direction with respect to a rotational axis of the steering shaft to an outer side of the cylindrical portion in the radial direction. The second housing member is provided on the other side in the rotational axial direction, and forms a housing together with the first housing member. The second housing member includes a connection portion and a containing portion. The connection portion is connected to the flange portion of the first housing member. The containing portion contains a part of the steering shaft. The bearing is provided at a position that overlaps the flange portion in the rotational axial direction on an inner peripheral side of the cylindrical portion of the first housing member, and supports the steering shaft.

An outer casing attachment structure includes a cables extending in a same direction, outer casings to which the inner cables is respectively inserted, a connecting member to which ends of the outer casings are connected, and a holding member including a holding part configured to hold the connecting member, wherein an installation space where the connecting member is disposed, and an opening provided in a direction perpendicular to an axis direction of the inner cables and configured to communicate between the installation space and outside are formed in the holding part, wherein the holding part includes a first retainer part and a second retainer part formed on both sides of the opening in an arrangement direction of the inner cables, and the connecting member includes a first engaging part configured to engage with the first retainer part, and a second engaging part configured to engage with the second retainer part.