A vehicle door control device 1 according to the present invention relates to a vehicle door control device 1 for controlling opening and closing of a door of a vehicle, wherein the vehicle door control device 1 comprises: a handle member 30 attached to the door; an entry detection sensor 31 for detecting entry of an object into a space between the door and the handle member 30; an external force detection sensor 32 for detecting application of an external force to the handle member 30; and a circuit portion 4 connected to the entry detection sensor 31 and the external force detection sensor 32, the circuit portion 4 releasing a latch of the door when the external force detection sensor 32 detects the application of the external force and the entry detection sensor 31 detects the entry of the object.

A vehicle door control device 1 according to the present invention relates to a vehicle door control device 1 for controlling opening and closing of a door of a vehicle, wherein the vehicle door control device 1 comprises: a handle member 30 attached to the door; an entry detection sensor 31 for detecting entry of an object into a space between the door and the handle member 30; an external force detection sensor 32 for detecting application of an external force to the handle member 30; and a circuit portion 4 connected to the entry detection sensor 31 and the external force detection sensor 32, the circuit portion 4 releasing a latch of the door when the external force detection sensor 32 detects the application of the external force and the entry detection sensor 31 detects the entry of the object.

A transmission mechanism for a vehicle door handle is provided, the handle including a handle lever, movable between a flushing position and a ready position, the mechanism attachable to the lever and to an electric motor, and including a lever shaft connectable to the lever, a rotation of which causes motion between the positions; a reduction mechanism to adapt an output torque of the motor into a rotational motion of the shaft, including first and second reduction stages each having a worm drive, the first including a first worm and a first worm gear, and the second having a second worm and another worm gear rotationally coupled to the shaft; and a brake mechanism frictionally engaging a rotating element of one of the stages when the shaft reaches a rotational braking position between the positions to stop the shaft in a position where the lever is in the ready position.

A decorative element with an actuation module for an electronic lock system where the actuation module may have at least an outer actuation element and an interior actuation sensor for triggering a switching function and an electronic evaluation unit that is connected to the actuation sensor. The decorative element may form the actuation element and the decorative element moves elastically when actuated, in particular to its actuation position. Also provided is a movable vehicle element with such a decorative element and a vehicle with at least one such movable vehicle element.

An opening control device including a base, a handle lever configured to be pivotally mounted on the base about a handle axis, a kinematic chain configured to transmit a movement from the handle lever toward a latch of the opening control device to unlock the door leaf, the chain including at least one active branch of the handle lever, an inertial safety member including a main body forming an inertial mass and a blocking element linked to the body and configured to prevent by wedging the transmission of movement by the kinematic chain. According to the invention, the inertial member is kinematically coupled to the secondary branch of the handle lever and extends on the side of the secondary branch with respect to the handle axis opposite to a gripping main branch.

The system includes a bracket, a handle pivotally mounted about a handle axis and including a main gripping branch and a secondary branch each extending on either side of the handle axis, a safety device configured to block an ejection of the handle towards its open position in the event of an impact. The device includes a blocking pawl elastically biased into a position of blocking the pivoting of the secondary branch according to a handle ejection direction and at least one lever for releasing the secondary branch in the ejection direction, the release lever being configured to drive the pawl, against its elastic biasing force, into a release position of the secondary branch, consecutively to a manual mechanical action of pushing in the handle from its flush position and/or to the triggering of an electric actuation for ejecting the handle from its flush position.

A handle assembly for a closure of a vehicle includes a force-based sensor disposed beneath an uninterrupted class-A surface and responsive to a force applied thereto. The handle assembly includes a handle ECU, configured to monitor the force-based sensor and to communicate with an electronic latch controller. A super-capacitor is disposed on a PCB within the handle assembly for providing electrical power to the handle ECU and the force-based sensor. The handle ECU includes one or more feedback devices such as LED lights, acoustic, and haptic devices to provide information about the status of the closure and the electronic latch system. The handle assembly is also configured to provide different responses to two or more different levels of force applied to the force-based sensor. An output interface in the handle assembly provides wired and wireless backup communications to the electronic latch controller.

A handle assembly for a closure of a vehicle includes a force-based sensor disposed beneath an uninterrupted class-A surface and responsive to a force applied thereto. The handle assembly includes a handle ECU, configured to monitor the force-based sensor and to communicate with an electronic latch controller. A super-capacitor is disposed on a PCB within the handle assembly for providing electrical power to the handle ECU and the force-based sensor. The handle ECU includes one or more feedback devices such as LED lights, acoustic, and haptic devices to provide information about the status of the closure and the electronic latch system. The handle assembly is also configured to provide different responses to two or more different levels of force applied to the force-based sensor. An output interface in the handle assembly provides wired and wireless backup communications to the electronic latch controller.

A vehicular exterior component, such as a handle assembly for a closure of a vehicle, includes a force-based sensor disposed behind an outer wall and responsive to forces applied thereto. The vehicular exterior component may include a force-sensitive printed circuit board (PCB) configured to detect touch forces at either of an inner surface or an outer surface of the outer wall of the vehicular exterior component and to distinguish between those different touch forces in order to provide corresponding unlock or lock signals. A short-range RADAR antenna may be disposed within the vehicular exterior component and adjacent to the outer wall. A passive keyless entry (PKE) antenna may also disposed within the vehicular exterior component and adjacent to the outer wall.

A vehicular exterior component, such as a handle assembly for a closure of a vehicle, includes a force-based sensor disposed behind an outer wall and responsive to forces applied thereto. The vehicular exterior component may include a force-sensitive printed circuit board (PCB) configured to detect touch forces at either of an inner surface or an outer surface of the outer wall of the vehicular exterior component and to distinguish between those different touch forces in order to provide corresponding unlock or lock signals. A short-range RADAR antenna may be disposed within the vehicular exterior component and adjacent to the outer wall. A passive keyless entry (PKE) antenna may also disposed within the vehicular exterior component and adjacent to the outer wall.