A method for constructing an extension mechanism for a closure panel of a vehicle, the extension mechanism including an extension member housed in a body housing, such that the extension member extends and retracts with respect to the body housing as the closure panel is opened and closed, the extension mechanism having a first connection at one end for connecting the extension member to the vehicle and a second connection at the other end for connecting the body housing to the vehicle, the method comprising the steps of: overlapping a tube wall of the body housing with an end portion of the body housing, the end portion having a receiving indentation; receiving a deformed portion of the tube wall into the receiving indentation in order to form a crimp connection between the tube wall and the end portion; and positioning a clamping member having a body by at least a portion of the body over the tube wall, such that the deformed portion is sandwiched between the portion of the body and the receiving indentation.

In a method for connecting a spindle (12) to a spindle holding element (14) in order to produce a longitudinal adjustment device (1) for a vehicle seat (16), a spindle (12) extended along a longitudinal axis (L) is cohesively using an connected to a connecting portion (142) of a spindle holding element (14) by using a resistance welding method. In this way, there is provided a method for connecting a spindle to a spindle holding element in order to produce a longitudinal adjustment device for a vehicle seat, which provides for a firm connection of a spindle to a guide rail via one or more a spindle holding elements, by a producing process that is easy to manage and to monitor.

The invention relates to a drive assembly of a motor vehicle (2) for the motorized adjustment of a hatch (3), in particular a side door, of the motor vehicle (2) by means of linear drive movements, wherein the drive assembly (1) for generating the linear drive movements has a drive unit (4) which is assigned a drive (5) having at least one drive motor (6) and a thrust gearbox (7), in particular a spindle/spindle nut gearbox (8), that in terms of drive technology is coupled to the drive (5), It is proposed that the drive assembly (1) has a support structure (9) which receives the drive unit (4) so as to be pivotable about a geometric supporting pivot axis (10), and that the drive unit (4) and the support structure (9) are connected so as to form a preassembled unit (13) which per se, by way of the support structure (9), is able to be assembled on an assembly location (14) on the motor vehicle (2), in particular on the hatch (3), or on the motor vehicle body (15).

A linear actuator includes a sliding rod, a motor and a buffer assembly. The motor connects the sliding rod to drive the sliding rod. The buffer assembly is disposed at an end of the sliding rod and includes an elastic element and an outer sleeve. The elastic element is received in the outer sleeve. The sliding rod connects the outer sleeve. The outer sleeve is movable along an axial direction of the sliding rod. The elastic element separately pushes an inner wall of the outer sleeve and the sliding rod. The elastic element is pre-compressed along the axial direction of the sliding rod. The buffer assembly can absorb vibration and impact caused by the motor driving the sliding rod.

A driving block, a linear actuator and an adjusting apparatus are provided. The adjusting apparatus comprises an executing mechanism and a linear actuator. The linear actuator comprises a driving block and a spindle. The driving block comprises a base, a changeover unit, a fastener and a limit unit. The base is in transmission connection with the spindle. The changeover unit includes a first mounting portion, a second mounting portion and a connecting portion. The first mounting portion and the second mounting portion are oppositely disposed on the base and are both connected with connecting portion. The first mounting portion and the second mounting portion are connected to the base by the fastener. The connecting portion is engaged with the executing mechanism, and the limit unit is used to restrict movement of the changeover unit relative to the base.

A spindle drive for a motorized adjustment of an adjustment element of a motor vehicle includes a tubular or half-shell-like spindle drive housing. An annular or disk-like connection portion is inserted and secured in one end region of the spindle drive housing. The annular or disk-like connection portion is connected via a damping element comprising a resilient damping material to a connection for discharging axial drive movements. The connection portion has a coaxial recess with an inner radially peripheral wall having a radially peripheral groove. The connection with the end region thereof facing the spindle drive housing protrudes axially into the recess of the connection portion and has a radially peripheral flange which protrudes radially into the groove. The damping element is arranged in a gap disposed between the side walls of the groove and the side walls of the flange.

A spindle drive assembly includes a threaded spindle rotatable about a spindle axis; a threaded spindle nut disposed on the threaded spindle and configured to travel along the spindle axis via a rotation of the spindle; a ball stud attached to the spindle nut, the ball stud extending radially away from the spindle nut; an attachment plate configured to be attached to a part to be moved; and a ball socket connected to the attachment plate and having a cavity dimensioned for receiving the ball stud. The cavity of the ball socket has a first diameter in a direction perpendicular to the spindle axis and a second diameter parallel to the spindle axis, wherein the first diameter is greater than the second diameter.

Apparatus and methods for actuating a double-slotted flap movably coupled to an aircraft wing are disclosed. An exemplary method comprises actuating a first panel of the double-slotted flap relative to a structure of the aircraft wing, using motion of the first panel to induce rotation of a slave screw, and using the rotation of the slave screw to actuate the second panel relative to the first panel.

An electromechanical-hydraulic piston actuator providing pressurized pressure medium for a brake system of a vehicle, including an electric motor having a stator and a rotor, a rotation-translation mechanism driven by the electric motor and which has a rotatable threaded nut and a threaded spindle prevented from rotating and displaceable in its axial direction, a piston coupled with the threaded spindle in the axial direction thereof, a hydraulic cylinder having a hydraulic chamber filled with pressure medium into which the piston is displaceable from a rear piston position towards a forward piston position to pressurize the pressure medium and/or expel it from the chamber. A hydraulic connection is connected to the chamber via which pressure medium can be expelled from the chamber. An isolation device is provided for the piston-travel-controlled isolation of the rotational coupling between the rotor of the electric motor and the threaded nut.

A coupling element for fitting to a threaded spindle. The coupling element has a receiving portion which is formed integrally with a coupling portion. The receiving portion extends in a hollow-cylindrical manner along an axis having an axial receiving opening for receiving the threaded spindle, and the coupling portion is flattened transversely with respect to the axis relative to the receiving portion and has a connection means. In order to be able to produce a coupling element in a more efficient and flexible manner, the receiving portion and the coupling portion be formed from a continuous integral pipe portion, wherein the coupling portion has a pressing portion in which the pipe portion is plastically compressed flat transversely relative to the axis.