Provided is a swing door operator (110) for moving a door leaf (120) between a first position and a second position. The swing door operator (110) is arranged to operate in a powered and a powerless mode and comprises a permanent magnet DC motor (310). The motor (310) is arranged to move the door leaf (120) at least from the second position to the first position in the powered mode. The swing door operator (110) further comprises a mechanical drive unit (320), arranged to move the door leaf from the first position to the second position in the powerless mode. In the powerless mode, at least one resistive device is electrically connected in parallel with the motor (310) and arranged to limit a current generated by the motor (310) in response to the movement of the door leaf (120) from the first position to the second position by means of the mechanical drive unit (320). A method for controlling the swing door operator is also provided.

Provided is a brake device for braking a rotational movement of a shaft about the longitudinal axis, wherein the shaft is mounted so as to be rotatable about the longitudinal axis in a direction of rotation and in a counter direction which opposes the direction of rotation. Brake devices typically use constant and relatively high braking torques, to ensure a controlled movement of a movement portion, braked by the brake device, in every situation. However, this increases the energy consumption for a movement of the movement portion, and the wear of the brake device. A brake device equipped with a setting device for mutually opposing setting of a braking torque on the shaft during rotation of the shaft in the direction of rotation, and a counter braking torque during rotation of the shaft in the counter direction is provided. Also provided is a method for controlling a brake device.

A method for pivoting a leaf from a closed position at an opening angle of 0° to an open position at an opening angle of greater than 0° and/or from the open position at the opening angle of greater than 0° to the closed position at the opening angle of 0° by a leaf torque, wherein the leaf toque has a manual torque, generated by a person, and a drive torque, wherein the drive torque is generated by a drive device with a drive module, a closer module and a controller module. The drive module has an electric machine having a stator and a rotor, wherein the closer module has an, in particular mechanical, energy storage, wherein the controller module has a controller device, wherein the drive torque has a machine torque generated by the electric machine and a closer torque generated by the closer module.

An actuator for a side door of a motor vehicle is described, which brings about automatic opening or closing of the side door depending on a signal and has a device for holding the side door in any open position. The holding device is realized by a function of the electric motor itself, according to which function the control device initiates a short-circuit function of the motor phases when the motor is activated, which causes a high current flow and thus a high torque for holding the side door open. By short-circuiting the motor phases, no additional components are required, since this is a special activation function of the motor.

A vehicle component has a sensor device that includes a sensor for detecting a characteristic parameter for an obstacle in the vicinity of the vehicle, for example an obstacle in a movement area of the door. The damper device can be actuated in a manner which is dependent on the parameter. A monitoring device is provided which, in order to detect a characteristic parameter for a manipulation of the vehicle, for example damage of a vehicle exterior shell or removal of a vehicle interior compartment, is operatively connected to the sensor device, in order for the latter to be interrogated.

A vehicular opening/closing body control device includes: a braking control unit configured to apply a braking force to an opening/closing body provided in an opening in a vehicle; a position detection unit configured to detect an opening/closing operation position of the opening/closing body; and a traveling state determination unit configured to determine a traveling state of the vehicle, wherein the opening/closing body is opened/closed along a movement path, which is formed by a guide rail and a guide roller engaged with the guide rail, the guide rail includes a curved portion, which is curved in a width direction of the vehicle, and the braking control unit executes braking control in a case where the opening/closing operation position of the opening/closing body is within a specific range, which is set in the movement path of the opening/closing body to correspond to the curved portion of the guide rail.

A vehicle door device includes: a braking control unit applying a braking force to a swing door of a vehicle by controlling an operation of a braking device; an action position detection unit detecting an action position of the swing door; and a vertical displacement detection unit detecting a vertical displacement of the swing door. The braking control unit does not execute braking control in a case where the action position of the swing door changes with the vertical displacement exceeding a predetermined gripping operation determination value, even in a case where an execution condition of braking control for applying the braking force is satisfied.

An adjusting device for a vehicle part which is movable relative to a body of a vehicle, includes a drive arrangement having a drive unit and a movement state sensor, an adjusting element which is displaceable relative to the drive arrangement via the drive unit and a control unit for controlling the drive unit. The control unit is designed to actuate the drive unit according to an actual movement state. The disclosure also relates to a motor vehicle having a body and a vehicle part movable relative to the body, which part is equipped with an adjusting device.

An assembly includes a first structure, a second structure, a hinge that connects the first structure to the second structure for rotation of the first structure relative to the second structure around an axis, and a motion control component. The motion control component applies a feedback force to the hinge in response to an external force that is applied to the first structure. A magnitude of the feedback force is determined based on a current angular position of the first structure relative to the second structure.

A hood energy management apparatus includes an energy dissipation feature having a magnetic component and a pneumatic component as well as a hood bumper carried on the energy dissipation feature. A related method of managing hood closing energy and also automatically providing proper hood fit and finish is also disclosed.