The present invention relates to a headrest moving device including a damper configured to generate a resistance force in a direction opposite to a moving direction when the headrest is moved, wherein, when the headrest is moved, the resistance force is different when the headrest is located at a first position from when the headrest is located at a second position, so that noise can be prevented from being generated and a user can be prevented from recognizing the moving of the headrest as a malfunction when the headrest is moved.

A track assembly includes a track, a support member, and/or a lever. The support member may be connected to the lever, and/or the lever may include a rotational axis substantially parallel to the track. The lever may rotation about the rotational axis between a first position and/or a second position. The lever may be configured to engage the track in a longitudinal direction when the lever may be in a first position. The lever may be configured to engage the track in a lateral direction when the lever may be in a second position. The lever may be configured to limit longitudinal movement of the support member along the track. The track may include a longitudinal window that may have a first edge and/or a second edge.

A track assembly includes a track, a support member, and/or a lever. The support member may be connected to the track, and/or the lever may be connected to the support member. The lever may include a rotational axis substantially parallel to the track. The lever may rotate about the rotational axis between a first position and a second position. The lever may limit movement of the support member relative to the track in a first direction, and/or the lever may not limit movement of the support member relative to the track in a second direction. The lever may be configured to contact the track. The track may include a window having a first edge and/or a second edge.

A track assembly includes a track, a support member, a lever, and a slider. The support member may be configured for selective connection with the track. The lever may be connected to the support member, and the slider may be connected to the support member. The lever may be configured to limit movement of the slider and to limit movement of the support member. The slider may be configured to move longitudinally along the support member. The slider may be connected at a top of the support member. The lever may be configured to rotate about an axis that may be parallel to the track. The lever may include a top portion. The lever may include a first position and/or a second position. The slider may be configured to selectively contact the top portion of the lever when in a first position.

A support assembly includes a support member, a side member, and a resilient member. The support member may be configured to engage a track. The resilient member may be connected to the support member, and/or the support member may be connected to the side member. The resilient member may be configured to compensate for different orientations of the side member. The resilient member may be configured to maintain a position of the side member relative to the track. The resilient member may be configured to compensate for different lateral positions of the side member relative to the track. The resilient member may be connected to a lateral side of the support member. The resilient member may be disposed proximate a first end of the support member, and/or a second resilient member may be disposed proximate a second end of the support member.

A cam assembly includes a pin, a first cam, a second cam, and/or a bearing. The first cam may be connected to the pin, and/or the second cam may be connected to the pin. A bearing may be configured to rotatable support the pin. The second cam may include a first portion and/or a second portion. The first portion of the second cam may be configured to contact a track in a first vertical position of the pin. The second portion of the second cam may be configured to contact said track in a second vertical position of the pin. The first portion may be vertically offset from the second portion. The first position of the pin may correspond to an unloaded state. The second vertical position of the pin may correspond to a loaded state.

It is provided an adjustment device for a vehicle subassembly comprises a guide rail which extends along a longitudinal direction, an adjustment assembly which is guided on the guide rail so as to be displaceable along the longitudinal direction and which is assigned to the vehicle subassembly, a spindle which is arranged on the guide rail, and an adjustment mechanism which is operatively connected to the spindle, is arranged on the adjustment assembly and has a mechanism housing and is able to be driven so that the adjustment mechanism can be displaced, together with the adjustment assembly, along the longitudinal direction relative to the guide rail. On the adjustment assembly there is arranged at least one retaining element, which has an opening which is delimited by an edge and through which the spindle extends. The at least one retaining element supports the mechanism housing on the adjustment assembly in a floating manner in such a way that the mechanism housing, together with the spindle, is movable with respect to the at least one retaining element with a bearing travel along a direction perpendicular to the longitudinal direction.

A coupler for coupling a cross-talk tube of a vehicle seat with a shaft of a dual recliner assembly. The coupler comprises a generally cylindrical body extending axially between an inboard end and an outboard end. The inboard end includes an inboard aperture having an inboard planar surface. The outboard end includes an outboard aperture having an outboard planar surface. The inboard planar surface and the outboard planar surface transition from an axially offset position to an axially aligned position when the coupler is installed with the cross-talk tube and the shaft of the dual recliner assembly.

An arm rest assembly and aircraft passenger seat including the same. The arm rest includes a friction mechanism for resisting abrupt rotational movements of the arm rest. A rotationally fixed frame member defining a rotational axis and receives a rotational member of the arm rest configured to rotate around the rotational axis. A groove formed in an outer circumferential surface of the rotational member seats a O-ring disposed between the groove and an inner circumferential surface of the frame member. Tolerance between the frame member and arm rest is such that the O-ring is held in the groove in a compressed state and frictionally engagement each of the rotational member and the frame member.

In a slide rail device for use in a vehicle, a lock control member comprises a pair of facing walls which face a pair of side walls of an upper rail and extend in upward and downward direction, and a pair of anti-rattle projections which project from the pair of facing walls toward the pair of side walls of the upper rail.