The current invention discloses a thrust lever ball head assembly comprising a thrust lever ball hinge and a thrust lever ball head. The thrust lever ball head comprises a main body of the thrust lever ball head and flange structures on both sides of the main body of the thrust lever ball head, wherein the flange structures and the main body of the thrust lever ball head are an integral part, and the flange structures on both sides of the main body of the thrust lever ball head work together with the thrust lever ball hinge to limit the thrust lever ball hinge inside the thrust lever ball head. The thrust lever ball head assembly of the present invention has a simple structure, high assembling efficiency, low manufacture costs, light weight, free of maintenance and completely fulfills the requirements of light weight.

The present disclosure describes an adaptive spring compression tool that streamlines and partially automates the joining of a vehicle suspension system with a vehicle body on an assembly line. The spring compression tool can be modified and programmed to accommodate various vehicle models, products, and design modifications without replacing the entire tooling system. Additionally, the spring compression tool of the present disclosure has a structure, a function, and an operation that facilitates the compression of a spring without exerting large forces on the vehicle body. In various embodiments, the spring compression tool comprises at least two independent drives that adjust the compression of a spring and the position of a suspension system to achieve a car line position with the vehicle body.

A suspension arm for multi-link suspensions of automotive vehicles, comprising a body formed by a hollow extruded profile the cross-section of which has a closed outer contour formed by side walls and comprising at least one inner partition internally splitting the profile into at least two inner cavities, the extruded profile having the length of the arm to be obtained, according to a longitudinal axis of the arm, where a central section of the arm is machined in at least one side wall having no inner partition extending therefrom without the machining ever reaching an inner partition, and where the side walls having the at least one inner partition extending therefrom comprise an end opening in each end area of the arm, between which the central section is arranged, and a method for making the suspension arm.

A system and method for manufacturing a top mount for a vehicle suspension includes loading a top mount body, a journal, and a plurality of knurled studs into a lower die assembly. The lower die assembly includes a stationary die base, a floating die top, and a pusher shaft. A pusher head assembly applies a downward pressure to insert the knurled studs into the top mount body, while the pusher shaft substantially simultaneously applies an upward pressure to insert the journal into the top mount body. The floating die top and the pusher head assembly are raised in tandem to eject the top mount from the stationary die base. The floating die top and the pusher head assembly then retract so that the top mount can be removed from the system.

This disclosure relates to methods for obtaining a suspension arm for automotive vehicles, wherein certain embodiments comprise obtaining two identical parts to form a body, where each part is obtained by means of: a) cutting a metal or composite sheet forming a base plane, such that a central segment and two ends are defined, b) drawing at least one hole in each end, c) stamping each part forming in its central segment two flanges consisting of a first flange and a second flange located on opposite sides of the central segment and oriented perpendicular to the base plane, where said flanges have an asymmetrical arrangement with respect to a midplane passing through the geometric centers of the holes of the two ends and is perpendicular to the base plane, the second flange being separated from the midplane a distance equal to the separation of the first flange from the midplane plus a distance at least equal to the value of the thickness of the sheet or plate.

A fabricated torque arm for use in a vehicle suspension, including a rod having a solid rectangular cross-section, the rod having a first end and an oppositely disposed second end, a first bushing hub, and wherein the rod is only a single piece cut from a metal plate or sheet, wherein the first bushing hub comprises cut tubing, wherein the first end of the rod has a radius that conforms to an outer surface of the first bushing hub, and wherein the first end of the rod is welded to the outer surface of the first bushing hub.