A drive assembly configured to adjust a motor vehicle closure element including a clutch assembly provided with an input connection and an output connection. The clutch assembly includes a main braking element, configured to brake a movement from the output side, and a freewheel assembly configured to engage the main braking element from movement of the output side and disengage the main braking element by means of a movement from the input side. The brake assembly includes an auxiliary braking element configured to produce a predetermined permanent braking action by means of which the auxiliary braking element acts at least against the movement introduced on the output side, and that the predetermined permanent braking action of the auxiliary braking element has to be overcome to enable the freewheel assembly to disengage.

A door roller includes a carriage member comprising a plurality of bores, and a plurality of roller assemblies connected to the carriage member, each roller assembly of the plurality of roller assemblies including a pivot bearing rotatably disposed within a bore of the plurality of bores and a pair of rollers coupled to the pivot bearing. Each wheel assembly is configured to pivot relative to the carriage member.

An automatic door operator operating on standard 120V/240V AC power utilizes a servomotor for operation, and thus no separate transformer is required for the operator. The servomotor incorporates programming to limit torque, and thus no slip clutch is required in order to allow manual operation of the door. Furthermore, because the servomotor has built-in control logic, no separate digital control logic is required. Because the position of the servomotor is continuously maintained, the relative position of the door with respect to a fully opened or fully closed position is always known, and no separate external signal is required in order to monitor the door position.

A door glass assembly is configured to reduce an impact noise generated when a door glass is moved upward/downward and may include a carrier plate coupled to a glass holder to which a door glass of a vehicle is secured. The carrier plate is installed inside a door of the vehicle so as to be movable upward/downward. A module plate, on which the carrier plate is installed so as to be movable upward/downward, is installed inside the door of the vehicle. A driving motor is provided to move the carrier plate upward/downward. The module plate and the carrier plate are provided with an impact noise preventing means for gradually decelerating and stopping the carrier plate when the door glass is being maximally moved upward or downward.

Systems and methods for providing a door seal system for top-hanging sliding doors. In some implementations, two angled mating surfaces are used, one angled surface on a fixed frame and one reversed angled surface on the slideable door panel. The slideable door panel slides directly parallel to the fixed door frame. A mating seal surface is created that is only in frictional contact for a small portion of the linear slide distance of the door panel. In some implementations, rather than placing two opposing angled seal surfaces, the sealing system has one angled surface on the fixed door frame. In such implementations, the sliding door panel is adjusted to be in a reverse angled orientation relative to the angled surface of the fixed door frame. Seal designs for the rear vertical edge of the slideable door panel are also provided herein.

An exemplary armature assembly is configured for use with a door control mounted to one of a door or a doorframe. The door control includes a rotatable pinion, and the armature assembly includes an armature, a shoe, and an elastic component. The armature has a first end and an opposite second end, and the first end includes an opening sized and shaped to receive the pinion at a first interface. The shoe is configured for mounting to the other of the door or the doorframe, and the second end of the armature is pivotally connected to the shoe at a second interface. In certain forms, the elastic component coupled with the armature and configured to absorb mechanical shocks at one of the first interface or the second interface. In certain forms, the elastic component is configured to absorb mechanical shocks along the length of the armature.

An apparatus (1) for opening and closing a lid (lid body) of a vehicle includes a linearly-movable shaft (10) supported by a housing (90) such that the shaft is linearly movable along, and nonrotatable around, an axial center (X10); and a rotary shaft (30) supported by the shaft such that it is linearly movable along and rotatable around the axial center. A stopper mechanism (50, 60) selectively blocks or permits the shaft to move from moving from a second position to a first position. The shaft has a main body (11) disposed within the rotary shaft (30) and an elastic body (80) provided on a terminal end portion of the main body (11). The elastic body includes a cushioning part (81) on a tip, a sealing part (83) around the main body, and a connecting part (85) connecting the cushioning part to the sealing part within the main body.

A device for moving a furniture part held on a furniture body of an item of furniture having a guide with at least one pivot arm for pivoting the furniture part from a closed position into an open position relative to the furniture body and back with a base unit with an anchor plate. The device includes a positioning mechanism with a positioning portion formed in an intermediate region between the at least one pivot arm and the base unit. During a pivoting movement of the pivot arm, the positioning portion contacts an abutment surface on the pivot arm and/or on the base unit. Fine positioning of the pivot arm in an axial direction relative to its pivot axis is configurable by contact of the positioning portion with the abutment surface if the pivot arm has an axial offset with respect to a setpoint bearing position of the pivot arm.

In a sunroof device, each support member and each driving shoe include a pressing portion and an elastic body, respectively, that, when the driving shoe moves from a first position toward a second position, come close to each other and, when the driving shoe is positioned between the second position and a third position, come into contact with each other. When the driving shoe is positioned between the second position and the third position, the pressing portion presses the elastic body in a direction perpendicular to a width direction. A length in the width direction of the elastic body is longer than the pressing portion.

An exemplary armature assembly is configured for use with a door control mounted to one of a door or a doorframe. The door control includes a rotatable pinion, and the armature assembly includes an armature, a shoe, and an elastic component. The armature has a first end and an opposite second end, and the first end includes an opening sized and shaped to receive the pinion at a first interface. The shoe is configured for mounting to the other of the door or the doorframe, and the second end of the armature is pivotally connected to the shoe at a second interface. In certain forms, the elastic component coupled with the armature and configured to absorb mechanical shocks at one of the first interface or the second interface. In certain forms, the elastic component is configured to absorb mechanical shocks along the length of the armature.