A vehicle side structure includes: a vehicle body side structure including a boarding opening through which an occupant gets into and out of a vehicle; a sliding door configured to slide to open and close the boarding opening; an upper support structure; a middle support structure; a lower support structure; and a drive unit located in an upper portion of the vehicle body side structure and configured to drive the sliding door to open and close via at least a part of the upper support structure. The upper support structure, the middle support structure, and the lower support structure are configured to support the sliding door in upper, middle, and lower portions of the vehicle body side structure in a vertical direction of a vehicle such that the sliding door slides, respectively.

A vehicular slide door apparatus includes a guide rail forming a sliding path. A cutout portion in a side wall portion of the sliding path forms an insertion opening for a guide roller. The apparatus includes a fixing portion at a first end portion in the cutout portion, a positioning portion at a second end portion in the cutout portion, a closing member that includes a fixed end fixed to the fixing portion and a free end positioned by the positioning portion and that closes the insertion opening, and a fulcrum forming portion forming a rotation fulcrum for the closing member. The fulcrum forming portion generates biasing force of displacing the free end outward. The free end is positioned in contact against the positioning portion located on an outer side of the sliding path. Thereby, the free end and the side wall portion form a continuous sliding contact surface.

A sliding/swing complex door for a vehicle includes a sliding door configured to be opened upon a first operation of an outside handle positioned on an outside of the sliding door, a swing door configured to be integrated and opened with the sliding door upon a second operation of the outside handle, and a fixing unit configured to be opened in such a way to be integrated and rotated with the swing door in a state in which the sliding door is fully opened.

A vehicle has a sliding door fitted with a rotatable brake member to apply a braking force to the sliding door when the vehicle is on a slope. The brake member is automatically rotated about a pivot axis X-X by a moveable member forming part of an actuator when the vehicle is resting on a slope into a position in which a braking force is applied to the sliding door by the interaction of the brake member with an elongate track in the form of a sliding door support track.

A vehicle door structure includes a door lock unit configured to lock a sliding door and a swing door when the sliding door is in a fully opened state, and a lock detection unit configured to detect a locked state between the sliding door and the swing door by the door lock unit. The door lock unit has a locking pin disposed at a guide body, a locking pin biasing member configured to bias the locking pin toward the swing door, and a fitting section formed at a slide rail and fitted onto the locking pin. The lock detection unit detects the locked state between the sliding door and the swing door by detecting the locking pin being fitted into the fitting section.

An extended range sliding door hinge may include a track bracket assembly and an intermediate bracket. The track bracket assembly is sized to be operatively received by a vehicle door track assembly. A first end of the intermediate bracket is movably mounted to the track bracket assembly so that the intermediate bracket may be moved with respect to the track bracket assembly between a retracted position and an extended position. A second end of the intermediate bracket is sized to operatively engage a vehicle sliding door. The extended range sliding door hinge allows the vehicle sliding door to be moved between a standard position when the intermediate bracket is in the retracted position and an extended position when the intermediate bracket is in the extended position.

A vehicle door structure 1 includes a lock mechanism 40. The lock mechanism 40 includes a portion to be locked 50 provided to a guided body 18, a first locking portion 60 arranged at a position that corresponds to the portion to be locked 50 when the slide door 6 is in the fully closed position, and a second locking portion 70 arranged at a position that corresponds to the portion to be locked 50 when the slide door 6 is in the fully open position. The portion to be locked 50, in the fully closed position or the fully open position, protrudes toward the first locking portion 60 or the second locking portion 70 and is locked by the first locking portion 60 or the second locking portion 70. The second locking portion 70 protrudes toward the portion to be locked 50 when the swing door 70 is opened.

The invention relates to a sliding door arrangement for a freezer cabinet, comprising a door frame (1), at least one sliding door (2), wherein the sliding door (2) is movable along the frame plane between an open position and a closed position, and a guiding device (3), wherein the guiding device (2) comprises roller arrangements (4) each with a first roller axis (5) and at least one guiding element (6) guiding the movement of the sliding door (2), characterized in that the guiding device (3) is designed in such a manner that the sliding door (2) moves transversely to the frame plane during a movement from the open position to the closed position, for which purpose the guiding element (6) has a parallel portion (7) and an end portion (8), and the roller arrangements (4) each have at least one further roller axis (9).

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 guiding assembly (300) for guiding a sliding door leaf (101) movable along a sliding door rail (110) is provided. The guiding assembly (300) comprises a bogie (130) having a first end (132) being provided with a first steering member (136) and a second steering member (138), and an opposite end (134) comprising at least one guiding element (122) being engaged with the sliding door rail (110), wherein the bogie (130) is connected to the sliding door leaf (101). The guiding assembly (300) further comprises a guiding rail (140) having first end section (140a) and a second end section (140b). The bogie (130) is configured to pivot relative the sliding door leaf (101) as the second steering member (138) travels along the guiding rail (140).