A device for operating opposite sliding doors of a vehicle includes a center rail mounted at a center inside a door and formed in a curved shape so that the door moves to the outside of a vehicle interior of the vehicle when the door is opened. A center roller is mounted on the vehicle body so as to correspond to the center rail. The center roller is configured to move the center rail by being coupled to the center rail when the door is opened or closed as a center bearing unit formed at one side of the center roller is seated on the center rail. The center roller has a center shaft formed at a position spaced apart from the center bearing unit such that the center shaft can rotate the center roller.

A roller unit to which a cable end of a cable pulled by a door actuator is attached moves with a slide door along a guide rail on a vehicle body, and includes: a coupling part coupled to the slide door; a guide roller supported by the coupling part and moving along the guide rail; a guide pin fixed to the coupling part and into which the cable end with a shaft hole is inserted; and a fastener retaining the cable end inserted in a leading end of the guide pin. A recess is formed toward a guide pin axial line at the leading end. An external diameter of the leading end is smaller than an internal diameter of the shaft hole. The fastener includes a supporting part supporting the cable end inserted into the leading end, from the leading end side, and a protrusion part engaged with the recess.

The invention relates to a drive device for driving an element, having the following: a toothed belt drive with a toothed belt, a frame element which forms two opposite connection plates and a connection wall that connects the two connection plates together, at least three elongated force driving elements which are secured to the toothed belt and are aligned parallel to the width (B) of the toothed belt and parallel to one another and which are arranged within the frame element, wherein a central force driving element is rotationally fixed to the two connection plates, and the end sections of each adjacent outer force driving element extend through curved elongated holes of the connection plate, whereby the outer force driving element can be pivoted and the end faces of the outer force driving elements have cylindrical projections, which are designed as axle stubs and each of which has a roller, outside of one of the connection plates, a toothed disc with tooth recesses for catching teeth of the toothed belt and force driving element recesses for catching the force driving elements, a non-linear guide path, at least some sections of which run parallel to the extension of the toothed belt and in which the rollers arranged on the outer force driving elements are guided, and a drive means which is connected to the frame element and is used to connect to the element to be driven.

A sliding roof system for a motor vehicle comprises a front lifting mechanism and a rear lifting mechanism which are assigned to a front and a rear edge respectively of a cover of the sliding roof system, as well as a connecting element which is arranged between the front and the rear lifting mechanisms. The rear lifting mechanism includes a lifting carriage with at least one lifting slotted guide, a lifting lever which is pivotably attached with one end to a fixed bearing and the other end of which has a guide element for the cover, and a translating lever which is pivotably connected to the lifting lever between its ends, wherein the translating lever is coupled to the lifting carriage by means of two sliders.

Provided is an opening/closing apparatus for a vehicle capable of protecting a cable configured to open and close an opening/closing body even when a large external force is applied to the opening/closing body. A cross-sectional shape of a cable holding groove in a direction crossing a longitudinal direction of a cable guide is an arc shape configured to be in surface contact with a closing-side cable and an opening-side cable. Accordingly, a pressing force applied to the closing-side cable and the opening-side cable can be dispersed in a wide range of the closing-side cable and the opening-side cable rather than only in one part.

A sliding door mechanism includes a track that is fixed in position relative to a door opening, a post fixed in position relative to the track, and a member that is moveable longitudinally with respect to the track, the member being configured to be guided by the track. The mechanism further includes an arm mounted to the member, the arm rotatable about a vertical axis and configured to be pivotably attached to the sliding door. The arm defines a slot that is configured to receive the post as the door is moved from an open position toward a closed position such that the post urges the arm to rotate relative to the carriage such that the arm transmits a force to the door to urge the door to move laterally into the door opening.

A slide door support device supports a slide door that opens and closes a door opening formed on a side surface of a vehicle body. The slide door support device includes first and second lower rails, an upper rail, and lower and upper guide units. The upper rail includes a straight portion extending to a vehicle front, and a curved portion curved so as to extend inward in a vehicle width direction as a position shifts from a front end of the straight portion to the vehicle front. The upper guide unit includes first and second upper guide rollers that move along the upper rail, an upper load roller rolling on a rolling surface that extends along the upper rail, and an upper rotational arm connected so as to be rotatable relative to the slide door and supporting the first and second upper guide rollers and the upper load roller.

A closure device for closing an access opening in a motor-vehicle body. An inner chamber is accessible via the access opening and the access opening can be closed by a cap element. The cap element is connected to a guide device, which is arranged in the inner chamber and via which the cap element can be adjusted between a closed position and an open position. The guide device is configured such that the cap element executes a pushing movement and a lifting movement as it moves between the closed position and the open position. The cap element, in the open position, is arranged in the inner chamber.

A motor vehicle having at least one side door opening formed in the body of the same and having a sliding door closing the same, wherein the side door opening has a sill structure for supporting and movably guiding the sliding door, wherein the sill structure has a hollow profile oriented in the vehicle longitudinal direction (x-direction) and formed as a welded part, and wherein the hollow profile on the vehicle exterior has a welding flange, extending along the sill structure and oriented in the vehicle vertical direction (z-direction), as a mounting flange for a door seal, which delimits an indentation formed in an upper section of the outer contour of the hollow profile. It is provided advantageously that a recess having at least one guide rail for a roller guide of the sliding door is disposed above the indentation, which recess is detachably secured to the sill structure.

A vehicle includes a chassis, a door track, a door operatively connected to the door track and adapted to move between a closed position and an open position, and a hinge assembly coupled to the door. The hinge assembly is movably coupled to the door track and includes a first bracket coupled to the door, a second bracket coupled to the first bracket, and a transport assembly coupled to the second bracket and adapted to move along the door track as the door moves between the open and closed positions. The transport assembly includes a coupling member for releasably coupling the second bracket to the transport assembly. Upon movement of the second bracket from the first position to the second position, the door moves to an extended open position with respect to the door track.