An extension mechanism for coupling with a closure panel to assist in opening and closing of the closure panel of a vehicle between a fully closed position and a fully open position of the closure panel, the extension mechanism including: an inner tube having an outer surface; an outer tube having an inner surface and overlapping the inner tube for at least a portion of the outer surface along an extension axis, such that the inner surface and the outer surface are adjacent to one another when overlapped; a first spring positioned along the extension axis in an interior of the outer tube; a second spring positioned along the extension axis in an interior of the inner tube; a seal positioned between the inner surface and the outer surface; and a stopper to engage the first spring at one end and engage the second spring at an opposite end such that the first spring and the second spring are in series with one another along the extension axis; wherein the one end and the opposite end are spaced apart from one another such that the seal is positioned between the one and opposite end.

An electromechanical strut is provided for moving a pivotal closure member between open and closed positions relative to a motor vehicle body. The electromechanical strut includes a drive mechanism having a motor-gearbox assembly, flex coupling assembly, and a spring-loaded supplemental friction assembly that are operable to drive a rotatable power screw. The drive mechanism converts rotary motion of the power screw into linear motion of an extensible member to move the extensible member between a retracted position corresponding to the closure member closed position and an extended position corresponding to the closure member open position. The motor-gearbox assembly includes a motor and a geartrain having an output component driven at a reduced speed relative to the motor speed. The flex coupling assembly is operably disposed between the output component and the power screw. The spring-loaded supplemental friction assembly generates and applies a supplemental frictional force to the flex coupling assembly.

An electromechanical strut is provided for moving a pivotal closure member between an open position and a closed position relative to a motor vehicle body. The electromechanical strut includes a drive mechanism having a motor-gearbox assembly and a flex coupling assembly that are operable to drive a rotatable power screw. The drive mechanism is operable to convert rotary motion of the power screw into linear motion of an extensible member to move the extensible member between a retracted position corresponding to the closed position of the closure member and an extended position corresponding to the open position of the closure member. The motor-gearbox assembly includes a motor and a planetary geartrain that is driven by the motor. The planetary geartrain includes an output component driven at a reduced speed relative to the motor speed and which has a drum segment. The flex coupling assembly is operably disposed in a radial orientation between the drum segment and the power screw.

A sliding roller assembly includes a plurality of blocks, configured to be connected in series, at least one roller device provided between each of the plurality of blocks, where the roller device includes a main body having at least one roller bearing disposed in the main body.

Provided is a sliding door device which can move a support shaft attached to a sliding door along an inclined portion of a rail by using a pull-in device. The rail (6a) is provided with the straight portion (11) for linearly guiding the support shaft attached to the sliding door (2) and the inclined portion (12) which is inclined with respect to the straight portion (11) and obliquely guides the support shaft. The straight portion (11) of the rail (6a) is provided with the pull-in device (15) which can capture a trigger (18) provided on the straight portion (11) of the rail (6a) and linearly move along the straight portion (11) of the rail (6a) when the sliding door (2) is closed. A pull-in force transmission part (20) for moving the support shaft along the inclined portion (12) of the rail (6a) is coupled to the pull-in device (15).

The present disclosure provides a flexible bottom shell, where the flexible bottom shell includes a first half shell, a second half shell, and a bendable part connected the first half shell and the second half shell, where the bendable part includes a plurality of connection plates, the plurality of the connection plates are successively bonded and are successively hinged together. Hinge pieces include a fixed plate, a fixed axle, and a pin axle. The fixed axle and the pin axle are perpendicular to a surface of the fixed plate. The fixed axle is connected to the fixed plate, and the pin axle is connected to the adjacent connection plates.

The invention relates to a furniture connecting fitting (10) having an attachment section (51, 53) for coupling to a cabinet body (110), wherein a kinematic arrangement (30) is coupled indirectly or directly to the attachment section (51, 53), wherein an assembly piece (80) is provided, which assembly piece has a fitting end (81) facing the attachment section (51, 53) and a furniture attachment end (81.3) facing away from the fitting end (81), wherein the attachment section (51, 53) has at least one locating element (55) which, in an assembly position, interacts with a mating element (85) of the assembly piece (80) to form a connection, which acts transversely to the furniture attachment end (81.3) in a form-fitting and detachable manner, wherein an actuating element (60) is provided, which can be moved between a release position and a blocking position, and wherein the actuating element (60) rests against a supporting section (52) to secure the assembly position in the blocking position. Such a furniture connecting fitting can be easily connected to and installed on a cabinet body even in a compact design.

The present disclosure provides a flexible bottom shell, where the flexible bottom shell includes a first half shell, a second half shell, and a bendable part connected the first half shell and the second half shell, where the bendable part includes a plurality of connection plates, the plurality of the connection plates are successively bonded and are successively hinged together. Hinge pieces include a fixed plate, a fixed axle, and a pin axle. The fixed axle and the pin axle are perpendicular to a surface of the fixed plate. The fixed axle is connected to the fixed plate, and the pin axle is connected to the adjacent connection plates.

A guide system for guiding at least one movably-supported door wing, in particular a folding-sliding-door, relative to a stationary furniture part. The guide system includes a carrier for movably supporting the at least one door wing, a guide rail configured to be fixed to the stationary furniture part for guiding the at least one carrier, a guiding device for displaceably supporting the at least one carrier along the guide rail, a running carriage configured to be coupled to the at least one door wing, and a receiving device for receiving the at least one running carriage. The receiving device adjoins the carrier in a longitudinal direction of the carrier, and the receiving device is movably supported relative the carrier in the longitudinal direction of the carrier.

A hinge includes a first end plate, a second end plate and at least one inner plate positioned between the first end plate and the second end plate. The first end plate is connected to the at least one inner plate by a first pin that extends through the first end plate and the at least one inner plate. The second end plate is connected to the at least one inner plate by a second pin that extends through the first end plate and the at least one inner plate. The first end plate is rotatable relative to the at least one inner plate about a first pivot axis defined by the first pin. The second end plate is rotatable relative to the at least one inner plate about a second pivot axis defined by the second pivot pin.