A buffer with a self-adjustable stopper including a buffer head, a base having a guide profile, and a central body having a groove cooperating with the profile, the central body being mounted on the base by a translation movement, in a first direction (X) in a plane of movement, the central body at least partially receiving the buffer head. The buffer head includes a locking member inserted into the central body in a second direction (Y) and blocks in a third direction (Z) the buffer head in the central body and blocking in the first direction the central body on the base. The locking element and the buffer head include, respectively, at least one thrust ramp and at least one housing adapted to receive said at least one ramp adapted to, when the locking member is translationally actuated, produce a camming effect and to allow raising of the buffer head.

A system for an automated cabin-divider door for an aircraft includes a door, a motor for moving the door to an open position, a limit switch configured to detect when the door is in a fully open position and to stop the motor, and electronics coupling the motor and the limit switch to an avionics system. The avionics system determines when the door is to be opened and provides a signal to the motor for moving the door to the fully open position. A method for automatically opening the cabin-divider door includes determining whether the aircraft is on the ground or in flight, determining whether the aircraft is taxiing, and determining whether the aircraft is in a final phase of approach. When the aircraft is taxiing or in the final phase of approach, the method includes sending a command signal to the motor for opening the cabin-divider door.

A drive arrangement configured to provide motorized adjustment of an adjusting element of a motor vehicle and including a motor, a driveshaft extending from the motor, an output shaft, a spindle configured to translate to adjust the adjusting element, a coupling configured to selectively couple and decouple the spindle from the motor, the coupling, a housing, and a sensor. The coupling including a coupling element configured to generate a signal indicative of rotation angle of the coupling element. The coupling, the output shaft and at least a portion of the driveshaft disposed in the housing. The sensor disposed in the housing and configured to detect the signal.

A hinge of a motor-vehicle mobile part includes a first and a second hinge element mounted articulated with respect to each other about a hinge axis. The second hinge element is articulated to the first hinge element by an articulation portion having two pins defining the hinge axis, and projecting in opposite directions from two sides of the second hinge element. The first hinge element and the second hinge element are obtained by an additive manufacturing technique in an already reciprocally articulated condition, with the pins mounted with clearance within respective articulation seats formed on two flanges of the first hinge element adjacent to the sides of the second hinge element. The hinge also includes two bushing-shaped members, each interposed between one of said two pins and the respective articulation seat.

In one aspect, an in-vehicle device is provided that includes a sensor configured to detect a vehicle characteristic indicative of the vehicle being in proximity to a location associated with a movable barrier operator. The in-vehicle device includes communication circuitry to communicate an open command to the movable barrier operator that causes the movable barrier operator to open a movable barrier connected to the movable barrier operator. A memory is configured to store a vehicle arrival condition indicative of whether the vehicle arrived at the location associated with the movable barrier operator. A processor is configured to determine satisfaction of the vehicle arrival condition and, upon the vehicle arrival condition not being satisfied, cause the communication circuitry to communicate a close command to the movable barrier operator that causes the movable barrier operator to close the movable barrier.

A contact sensor and method of construction thereof are provided. The contact sensor has a sensor body extending along an axis between a first end and an opposite second end. The sensor body has an internal cavity extending from the first end to the second. A first conductor extends through the internal cavity between the first end and the second end. A second conductor extends through the internal cavity, in spaced relation from the first conductor, between the first end and the second end. A wire harness is fixed in electrical communication with the first conductor and the second conductor adjacent at least one of the first end and the second end of the sensor body. The first conductor and the second conductor do not extend axially outwardly from the internal cavity beyond the first end and the second end of the sensor body.

The disclosure relates to a control device for a motor vehicle, having a sensor unit that is configured to contactlessly detect an object in a sensor zone situated on an outer side of the motor vehicle, and a control unit that is configured to generate a first control signal for at least one actuator according to the detected object, which a movement of an access element can be influenced. In order to improve the reliability and user-friendliness of a control device of a motor vehicle comprising a contactless sensor system, it is provided that the control device comprises a projector unit that is configured to project a light pattern that marks off at least one portion of the sensor zone.

Lockbox systems for securing items in a vehicle. In one embodiment, a hollow rectangular body has an open side which may be closed by a door. One or more L shaped locking members are disposed on the rear of the door adjacent a first longitudinal side. As the door is closed, the members are positioned to reside in locking recesses in a wall of the body, abuttably locking the door at the hinged side. Near a second side of the door, a locking mechanism is disposed that can be actuated to move a locking bolt into a bolt recess to secure the door in the body opening. The rear side surfaces of the door may be beveled to pair against a ridge disposed inside the opening to deter attempts to pry the door open.

A door operating mechanism displaces a door between a closed position and a deck position relative to a structure including a frame with a side door jamb and a head door jamb. The door operating mechanism includes a motor, and an actuator connected to the motor and disposed within the side door jamb. A cable is connected at one end to the actuator and at an opposite end to the door via a pulley assembly. A wire harness system electrically connects the motor to a plug connector. A control panel is mounted adjacent the door and is coupled with the motor via the wire harness system.

The disclosure concerns a method for controlling a sliding door arrangement of a motor vehicle, wherein the sliding door arrangement comprises a sliding door, a drive arrangement for motorized displacement of the sliding door, a control arrangement and a sensor arrangement with at least one sensor element, in particular implemented as a proximity sensor, where-in during operator event monitoring by means of the control arrangement the sensor signals of the sensor arrangement are monitored as to whether a predetermined operator event exists. It is proposed that the sensor arrangement is disposed at least partly in or on the sliding door and that opening the sliding door at least from a closed end position and/or closing the sliding door at least from an open end position is/are carried out by means of the drive arrangement depending on the result of the operator event monitoring.