The present invention relates to a stabilizer for a vehicle which is installed between a pair of wheels of the vehicle and includes a first bar disposed to extend in a width direction of the vehicle; an actuator supported by a vehicle body of the vehicle and coupled to the first bar and a first connecting member to move the first bar in the width direction of the vehicle; and a second bar having one side connected to the first bar and the other side connected to one side of a wheel supporter which supports one wheel of the pair of wheels of the vehicle, wherein, when the first bar is moved in the width direction of the vehicle, the other side of the second bar is moved so that the one side of the wheel supporter is moved in an upper direction or a lower direction of the vehicle.

The objective of the present invention is to improve the rigidity of a vehicle knuckle made from an aluminum alloy with respect to a force directed from the outside to the inside in the width direction of a vehicle. A vehicle knuckle (11) is provided with a bearing support portion (111), a knuckle upper portion (113) and a knuckle lower portion (112). With the vehicle knuckle (11) in a position fitted to a vehicle main body, the knuckle upper portion (113) has a shape in which, if the knuckle upper portion (113) is divided equally into five or more regions in a vertical direction, and the center of the bearing support portion (111) is fixed and a horizontal load F is applied to a knuckle upper end portion (115) from the outside toward the inside in the width direction of the vehicle, the minimum value of a value obtained by dividing the strain energy in each of the five or more regions other than a first region (11A) by the mass of the corresponding region is at least equal to 0.70 times the maximum value thereof.

A suspension linkage for a motor vehicle includes an extruded body having a first wall and a longitudinal length. An extruded feature is disposed on the first wall of the extruded body and extends along the longitudinal length. The extruded feature has a cross-sectional profile configured to control a flexural rigidity of the suspension linkage.

A stabilizer for a chassis of a vehicle, having a curved stabilizer body (2) that forms a torsion spring, with a pendulum support (5, 6) and with a connecting section (7, 8, 46, 48), the connecting section (7, 8, 46, 48) is made of a metal and connects the stabilizer body (2) to the pendulum support (5, 6). The connecting section (7, 8, 46, 48) and the stabilizer body (2) are connected to one another by a snap-in and/or latch joint. To reduce assembly effort and expense and, at the same time, to join the stabilizer body (2) to the pendulum support (5, 6) in a secure manner, the stabilizer (1) and the pendulum support (5, 6) are characterized in that the connecting section has an opening (22) in which a plastic bearing shell (11) is arranged for fitting of a joint ball (23) of the pendulum support (5, 6).

There is provided a vehicular suspension arm used for a suspension device of a vehicle. The vehicular suspension arm according to an embodiment of the present invention may comprise: a body portion constituting a basic body of the vehicular suspension arm; and a mounting portion formed in one end of the body portion and configured to connect the vehicular suspension arm to a wheel or a vehicle body of the vehicle, wherein the body portion may have a closed-box-section structure in which a hollow inner space is defined, and the closed-box-section structure may be configured such that the body portion is formed to integrally extend around the hollow inner space.

An aluminum alloy forging of the present invention includes 0.15 wt % to 1.0 wt % of Cu, 0.6 wt % to 1.3 wt % of Mg, 0.60 wt % to 1.45 wt % of Si, 0.03 wt % to 1.0 wt % of Mn, 0.2 wt % to 0.4 wt % of Fe, 0.03 wt % to 0.4 wt % of Cr, 0.012 wt % to 0.035 wt % of Ti, 0.0001 wt % to 0.03 wt % of B, 0.25 wt % or less of Zn, 0.05 wt % or less of Zr, the balance being Al and inevitable impurities. When integrated intensity of a diffraction peak of an AlFeMnSi phase in an X-ray diffraction pattern obtained by an X-ray diffraction measurement of a cross-section of the forging is “Q.sub.1” (cps.Math.deg) and integrated intensity of a diffraction peak of a (200) plane of an Al phase is “Q.sub.2” (cps.Math.deg), a value of Q.sub.1/Q.sub.2 is 6×10.sup.−2 or less.

An efficient method for producing spring strut forks for motor vehicles is presented. In each case two spring strut forks are produced from a metallic extruded profile as a starting product. The extruded profile has a central, middle main chamber and four longitudinal chambers which are arranged offset with respect to one another over the circumference of the main chamber. Wall portions of the main chamber which are situated between the longitudinal chambers are removed, and the extruded profile is severed into two semifinished parts. Each semifinished part has one cylinder portion and two oppositely situated arm portions which project relative to the cylinder portions. The semifinished parts are subsequently mechanically machined, and one spring strut fork is produced from each semifinished part.

A gas cup for a damper assembly comprises a body including an upper surface, a lower surface, an exterior surface and an interior surface. The body defines an aperture extending through the upper surface and the lower surface. A decoupler is located in the aperture and secured to the body. A bridging member is located between the decoupler and the body and coupled to the decoupler and the body. The decoupler and the bridging member is made from materials having different elasticity to allow the decoupler to move in the aperture in response to a volumetric change in the damper assembly and to provide variable tuning of the damper assembly. A damper assembly including the gas cup is also disclosed herein.

A suspension strut fork that has an upper portion which is constructed in an integral, materially uniform manner in the form of a suspension strut receiving member. Members and fork arms protrude therefrom in an integral, materially uniform manner. A gap is provided between the members. Via this gap, the members can be moved toward each other so that a resilient and/or damper element which is arranged in the suspension strut receiving member is securely clamped.

A twist beam for a suspension of a motor vehicle comprises a body-side inner part having a bearing-receiving section for receiving a body-side bearing, and a wheel carrier-side outer part having a bearing-receiving section for receiving a wheel carrier-side bearing, the outer part and the inner part being separate components which are made of different materials and are firmly connected to each other.