In an arrangement which includes: a seat support body slidably supported on a fixed rail fixed to a floor; a power supply device supplying power to an electrical component on a seat side; and a drive device driving the seat support body in a front-and-rear direction and having a motor and a transmission member disposed so as to pass longitudinally through an interior of the fixed rail, the power supply device includes: a housing an electric wire for power supply; and a slider linked to the seat support body and slidable within the fixed rail. The electric wire is drawn out from the housing, retained by the slider and slidable within the fixed rail. The slider has an interference-avoiding portion for avoiding interference with the transmission member disposed so as to pass longitudinally through the interior of the fixed rail. Accordingly, the transmission member of the drive device and the slider for retaining the electric wire, which slides within the fixed rail, can be arranged in proximity to each other within the fixed rail while avoiding interference therebetween, thus enabling simplification and a reduction in the size of a rail structure.

A vehicle seat adjustment mechanism may include a gearbox, a first gear, a second gear, and a spindle screw. The first gear is received in the gearbox and is rotatable relative to the gearbox about a first axis. The second gear is received in the gearbox and is rotatable relative to the gearbox about a second axis that is perpendicular to the first axis. The first and second gears are meshingly engaged with each other. The spindle screw is meshingly engaged with the second gear and extends through the second gear along the second axis. The spindle screw may have trapezoidal threads.

A seat rail assembly capable of stably holding a position of one or more vehicle seats relative to the vehicle floor. The seat rail assembly includes an upper rail on which the seat is provided and a lower rail which is mounted to the vehicle floor. The upper rail is slidably provided within the lower rail, and incorporates an engagement assembly with a dual wedge engagement assembly to ensure constant contact between the lower and upper rails. A gearbox configured to remove lash may be provided on the upper rail for moving the upper rail relative to the lower rail.

The present disclosure provides an auxiliary handle device configured to be used in entering or exiting a vehicle. The auxiliary handle device includes a cover unit including first and second movement guides, which define a movement path, a guide frame unit, which is connected to the cover unit so as to be slidably moved along a rail of a mounting plate mounted on a roof of the vehicle, and a handle unit, which is mounted on the cover unit so as to be selectively projected downwards from the mounting plate, the handle unit including a first guide pin and a second guide pin, which are respectively mounted in the first movement guide and the second movement guide such that the first and second guide pins are moved while being rotated so as to project the handle unit downwards from the mounting plate.

A seat system includes: a base; a seatback; at least one recliner connecting the base and the seatback to each other for pivoting of the seatback relative to the base; a slider coupled to the base and configured for sliding engagement with a track having a detent region and a tilt-and slide region; and an electronic controller, wherein without mechanical interlock between the recliner and the slider, the electronic controller causes the recliner to place the seatback in a non-passenger position when the slider is within the tilt-and-slide region, and causes the recliner to place the seatback in a passenger position when the slider is within the detent region.

A longitudinal adjuster for a motor vehicle seat may have a seat rail that can be connected to the vehicle seat, and a floor rail, which can be connected to a vehicle floor and on which the seat rail is displaceably guided. The longitudinal adjuster may have a drive device for adjusting the seat rail relative to the floor rail along the longitudinal direction. The drive device may have a spindle fixed to the floor rail or to the seat rail. A rotatable spindle nut may be mounted on the spindle via a thread engagement. An electric motor may be operatively connected to the spindle nut for driving the spindle nut. A drive-side output shaft of the electric motor may be oriented parallel to the spindle. The floor rail has a cut-out and the electric motor is at least partly arranged through the cut-out.

The embodiments described and claimed herein are improved vehicle access systems. In particular, one embodiment includes three compact, motorized mechanisms for pivoting a passenger seat toward a door opening, extending the passenger seat outside the door opening, lowering the passenger seat, and tilting the passenger seat to help the passenger stand. The first mechanism concurrently pivots the passenger seat and moves it sideways during the pivoting operation so that it is aligned with the door opening. The second mechanism extends the passenger seat outside the door opening. The third mechanism lowers the seat.

An adjustment system for a seat has a first bearing shell for receiving a seat surface and/or a seat backrest, a second bearing shell for connecting to a substructure, a first wedge-shaped adjustment ring, which is rotatably mounted on the first bearing shell, a second wedge-shaped adjustment ring, which is rotatably mounted on the second bearing shell and rotatably mounted on the first adjustment ring, a first drive for rotating the first adjustment ring relative to the second adjustment ring, a second drive for rotating the second adjustment ring relative to the second bearing shell, and a blockade mechanism for electively connecting the first bearing shell and the second bearing shell for conjoint rotation.

Provided is an electrically powered slide rail that can operate in a smooth manner. The electrically powered slide rail includes a rail having a channel-shaped cross section and extending in a fore and aft direction, a slider received by the rail and slidably engaged by the rail, a screw assembly including a screw member supported by the slider so as to be rotatable around an axial line extending in the fore and aft direction, an electric motor supported by the slider and configured to rotate the screw member, and a screw engaging portion formed in the rail so as to extend in the fore and aft direction and engage the screw member. In the vehicle seat fitted with the electrically powered slide rail, the rail is connected to a floor of a vehicle, and the slider is connected to a seat cushion.

A vehicle seat including a foldable seat kinematic which has a backrest part and a seat part, the seat kinematic being adjustable between a normal position and a folded-forward functional position, the seat kinematic being manually foldable from the normal position into the functional position, a motor, an activating system which is adapted to be driven by the motor between a deactivated position and an activated position, a connecting rod provided between the activating system and the seat kinematic. The seat kinematic is movable from the functional position into the normal position by the activating system and the connecting rod when the motor is actuated so as to drive the activating system from the deactivated position to the activated position, the activating system being configured to not interfere with the seat kinematic when the activating system is in the deactivated position.