A method for granting an access authorization for luggage compartments of a vehicle that has at least two luggage compartments, includes booking of a luggage compartment for a journey of the vehicle. At least one of the luggage compartments of the vehicle is assigned to the passenger via a central computing unit such that the passenger receives an access authorization. A request for granting a release of the at least one luggage compartment assigned to the passenger is input into a device. The access authorization of a person inputting the request is checked via a computing unit inside of the vehicle and/or the central computing unit. If checking by the computing unit, the computing unit obtains access authorization data from the central computing unit. If the person inputting the request is authorized, the at least one luggage compartment assigned to the passenger is released.

An embodiment of the present disclosure provides a swing-in type of door structure of a vehicle that includes a door disposed in parallel at both sides of an entrance of a vehicle, and a door arm mounted on one side of the door to open or close the door by rotation, including: a center door bracket of which one end is fixed to one surface of an upper center of the door and that extends in a direction perpendicular to the door; a roller bracket of which one end is coupled to the other end of the center door bracket in a direction perpendicular to the center door bracket; and a roller mounted on the other end of the roller bracket and coupled to be rolled and rotated while in contact with a rail formed on a vehicle body of an upper side of the door.

At least one leaf of this door is equipped with a detection device comprising a mechanical detection device and a contactless sensor each capable of detecting a presence. The control circuit board comprises a control unit for movement of each leaf and a diagnostic unit, while means transfer, from the detection device in the direction of the diagnostic unit and the control unit, a first item of information representative of the activation state of the mechanical device, and a second item of information representative of the activation state of the contactless sensor. The diagnostic unit can identify a malfunction at least of the contactless detection device, when the first item of information has an active value while the second item of information has an inactive value. The invention allows redundancy to improve the availability of the detection device, while performing predictive maintenance for the operator, in particular a malfunction of the contactless sensor.

A vehicle includes sensors that monitor at least part of the outer shell of the vehicle. The sensors have monitoring sensors for detecting vandalism. The vehicle has a monitoring system using the monitoring sensors and the monitoring system includes monitoring sensor electronics which are set up to operate the monitoring sensors at least also in the parked state of the vehicle. The vehicle includes automatically closing doors and the sensors have operating sensors for detecting the position of passengers as well as an entry system using the operating sensors, which serves to detect the position of passengers, in order to prevent a jamming of passengers during the automatic closing of the doors. At least one sensor is configured both as an operating sensor and a monitoring sensor and is used both by the monitoring system and also by the entry system.

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 window assembly includes a frame with a track, and a sliding window portion disposed in the frame and displaceable in the track between a closed position and an open position. The sliding window portion includes a handle pivotable between a lock position and a slide position, and a driving pin coupled with the handle and engaging the track. The driving pin defines a pivot axis for the handle. A guide pin spaced from the driving pin is selectively engageable with the track when the handle is pivoted from the lock position to the slide position. With the handle in the slide position, the sliding window portion is displaceable from its closed position to an open position.

A run-up type swing-out door retainer structure includes in a door retainer for a vehicle, a body retainer mounted at a body of the vehicle; and a door retainer mounted at a door of the vehicle to abut the body retainer. A depression formed at the end portion of the body retainer and a protrusion formed at the end portion of the door retainer are divided into an inclined section and a round section to abut each other.

The present invention relates to a vehicle control device provided in a vehicle and a control method of a vehicle. A vehicle control device according to an embodiment of the present invention includes a beam output unit for irradiating light to a road surface of a periphery of a vehicle, and a processor for sensing whether an object approaching toward a vehicle door is present or not via a sensing unit provided in the vehicle when a control command for opening the vehicle door is received after the vehicle stops, and, controlling the beam output unit so that information notifying the object approaching toward the vehicle door is irradiated to the road surface of the periphery of the vehicle door in a state in which the vehicle door is closed based on the presence of the object approaching toward the vehicle door.

A locking apparatus for a flap door of a vehicle includes: a body bracket fixed on a vehicle body; a flap bracket fixed on the flap door; a lower side link with a first end connected to the flap bracket and a second end connected to the body bracket; an upper side link with a first end connected to the flap bracket and a second end connected to the body bracket at an upper side of the lower side link; a stopper groove and a stopper protrusion provided on the first end of the upper side link; a locking cam mounted to a rotational shaft of the lower side link relative to the flap bracket, while being in contact with the stopper groove and the stopper protrusion; and a spring installed between the flap bracket and the locking cam to elastically switch a direction of rotating the locking cam.

A method for monitoring condition of a door on a vehicle, the door includes a first panel, a second panel, a first motor, a second motor, a first striker/latch assembly, and a second striker/latch assembly. The method includes steps of generating status indicators and communicating those indicator to a computer on the vehicle. The computer processes those status indicators to determine action regarding the vehicle.