Field of the Disclosure
The present disclosure relates to the placement of stress risers in automotive vehicle suspension arms to provide predictable suspension failure modes and movement of tire-and-wheel assemblies during offset frontal type collisions.
Description of the Related Art
Suspension arms locate the tire-and-wheel assembly in the vehicle and define the locus path of the tire-and-wheel assembly. During an offset frontal collision, the position and movement path of the front tire-and-wheel assembly during impact can influence both the crash energy load path and the intrusion amount into the passenger compartment.
The present disclosure relates to a suspension arm adapted for use in a suspension system of an automotive vehicle, and more particularly to a suspension arm of the type which has a pair of spaced mounting portions mounted on a vehicle body structure at two positions and a support portion supporting thereon a tire-and-wheel assembly. By adding a frangible feature to the bushing collar of a suspension arm, a breakage mode and timing can be optimized to ensure that a tire-and-wheel assembly consistently contacts surrounding parts at the desired time and locations during a vehicle impact event.
A more complete appreciation of the disclosure and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
As shown
The front mounting portion 10b of suspension arm 10 is in the form of a cylindrical sleeve that is mounted on the vehicle through a bushing collar 11. The longitudinal axis of the bushing collar 11 is in the first direction. The front mounting portion 10b of suspension arm 10 is mounted on the vehicle for rotary movement about the longitudinal axis of the first direction. The rear mounting portion 10c of suspension arm 10 is in the form of the cylindrical sleeve that is mounted on the vehicle for rotary movement about an axis line orthogonal to the first direction, for example substantially in a vertical direction. The outboard portion 10d of the suspension arm 10 is connected to a carrier of a tire-and-wheel assembly by a ball joint in a usual manner. The suspension arm 10 can be formed by a variety of processes, for example casting or forging. The bushing collar 11 can be formed by a variety of processes, for example forging, welding, stamping, or extrusion. The material of the bushing collar 11 may have a different composition and hardness than the material of the suspension arm 10.
The bushing collar 11 of the front mounting portion 10b of the suspension arm 10 is equipped with a frangible portion. As used herein, the term “frangible portion” means structure intended to breakaway in an impact collision.
As shown in
Notches 12a and 12b create stress risers and allow optimization of the breakage mode and breakage timing of the bushing collar 11 and front mounting portion 10b to ensure a tire-and-wheel assembly consistently contacts surrounding parts at desired times and locations, in a predictable sequence and manner, during a vehicle impact event.
Although the bushing collar 11 in the above-described embodiment is provided two notches 12a and 12b, it is obvious that said bushing collar 11 can be provided at least one notch.
As shown in
By adding axial groove 13 to the bushing collar 11 of the suspension arm 10, the breakage mode and breakage timing can be optimized to ensure a tire-and-wheel assembly consistently contacts surrounding parts at the desired time and locations, in a predictable sequence and manner, during a vehicle impact event.
Although in the above-described embodiment the axial groove 13 is formed inside a circumference of the bushing collar 11, it is obvious that the axial groove 13 can be formed outside circumference of said bushing collar 11. Also, it is obvious that the axial groove 13 can be formed on a side of the collar proximal from the arm member.
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