The Effects of Chassis Flexibility on Roll Stiffness of a Winston Cup Race Car

To validate the model, the change in wheel loads due to an applied jacking force that rolls the chassis agrees closely with measured data. The roll stiffness predicted from finite element models of the front and rear suspension compared closely to those calculated using a rigid-body kinematics model. To study the effects of chassis flexibility on roll, torsional stiffness is increased by adding strategic members to the chassis structure. Results from the finite element analysis indicate that the effective roll stiffness of the front suspension interacting with the chassis, increased by 7.3 % over a baseline chassis when the chassis torsional stiffness was increased by 130% over a baseline chassis stiffness of 9934 ft-lb/deg. As the chassis stiffness is increased further above this value, the front roll stiffness changed very little. From these results, the minimum torsional stiffness required so that the effective roll stiffness of the front suspension is within 3 % from the roll stiffness with a rigid chassis, is about 23100 ft-lb/deg.