Brake-Dive Sensitivity Analysis Using a Five-Degree-of-Freedom
Lumped-Mass Model and Design of Experiments 2022-01-5099
The sensitivity of the brake dive of a sport utility vehicle (SUV) was analyzed
using a five-degree-of-freedom (5-DoF) lumped-mass model and design of
experiments (DoE). A program was developed and validated using Visual Basic for
Applications (VBA). The analysis parameters used actual kinematics and
compliance (K&C) data without linear assumptions, enabling detailed
numerical and systematic descriptions of previously unorganized knowledge
obtained from the experiences of tuning engineers. The initial shock and
residual ripple of the nose-dive angle were defined as DoE performance metrics,
and the required suspension parameters and shock absorber piston speeds were
identified. The initial shock was greatly influenced by the rear and front
spring forces, followed by the rear rebound damping, rear anti-lift force, and
front anti-dive force. Further, the residual ripple was highly sensitive to the
front and rear rebound damping forces. The initial shock can be improved to some
extent by applying only shock absorber tuning to effectively reduce the residual
ripple.
Citation: Wang, H., Fan, H., Li, X., Bai, F. et al., "Brake-Dive Sensitivity Analysis Using a Five-Degree-of-Freedom Lumped-Mass Model and Design of Experiments," SAE Technical Paper 2022-01-5099, 2022, https://doi.org/10.4271/2022-01-5099. Download Citation
Author(s):
Hai-Dong Wang, Hong-Chun Fan, Xiao-Shan Li, Fan Bai, Sung-Mo Yang