Design Optimization of Quarter-car Models with Passive and Semi-active Suspensions under Random Road Excitation

A methodology is presented for optimizing the suspension damping and stiffness parameters of nonlinear quarter-car models subjected to random road excitation. The investigation starts with car models involving passive damping with constant or dual-rate characteristics. Then, we also examine car models where the damping coefficient of the suspension is selected so that the resulting system approximates the performance of an active suspension system with sky-hook damping. For the models with semi-active or passive dual-rate dampers, the value of the equivalent suspension damping coefficient is a function of the relative velocity of the sprung mass with respect to the wheel subsystem. As a consequence, the resulting equations of motion are strongly nonlinear. For these models, appropriate methodologies are first employed for obtaining the second moment characteristics of motions resulting from roads with a random profile. This information is next utilized in the definition of a vehicle performance index, which is optimized to yield representative numerical results for the most important suspension parameters. Special attention is paid to investigating the effect of road quality as well as on examining effects related to wheel hop. Finally, a critical comparison is performed between the results obtained for vehicles with passive linear or bilinear suspension dampers and those obtained for cars with semi-active shock absorbers.

[1]  John C. Dixon,et al.  Tires, Suspension and Handling, Second Edition , 1996 .

[2]  G. Verros,et al.  DYNAMICS OF LARGE SCALE VEHICLE MODELS USING ADAMS/FLEX , 2000 .

[3]  G Verros,et al.  DYNAMICS OF VEHICLES WITH SEMI-ACTIVE SUSPENSIONS EXHIBITING WHEEL HOP , 2001 .

[4]  Cecilia Surace,et al.  An improved nonlinear model for an automotive shock absorber , 1992, Nonlinear Dynamics.

[5]  G. Verros,et al.  Control and Dynamics of Quarter-Car Models With Dual-Rate Damping , 2000 .

[6]  P. Spanos,et al.  Random vibration and statistical linearization , 1990 .

[7]  M. Shinozuka,et al.  Simulation of Stochastic Processes by Spectral Representation , 1991 .

[8]  S. Sarkani,et al.  Stochastic analysis of structural and mechanical vibrations , 1996 .

[9]  J. D. Robson,et al.  The description of road surface roughness , 1973 .

[10]  Masanobu Shinozuka,et al.  Monte Carlo solution of structural dynamics , 1972 .

[11]  Jörg Wallaschek,et al.  Dynamics of non-linear automobile shock-absorbers , 1990 .

[12]  Roman B. Statnikov,et al.  Multicriteria Optimization and Engineering , 1995 .

[13]  Paul Malliavin,et al.  Stochastic Analysis , 1997, Nature.

[14]  Massimiliano Gobbi,et al.  ANALYTICAL DESCRIPTION AND OPTIMIZATION OF THE DYNAMIC BEHAVIOUR OF PASSIVELY SUSPENDED ROAD VEHICLES , 2001 .

[15]  Costas Papadimitriou,et al.  Fault Detection and Optimal Sensor Location in Vehicle Suspensions , 2003 .

[16]  Davorin David Hrovat Applications of Optimal Control to Advanced Automotive Suspension Design , 1993 .

[17]  T D Gillespie,et al.  Fundamentals of Vehicle Dynamics , 1992 .

[18]  S. Natsiavas,et al.  Dynamics of Multiple-Degree-of-Freedom Oscillators With Colliding Components , 1993 .

[19]  Robert F. Harrison,et al.  Approximate, time domain, non-stationary analysis of stochastically excited, non-linear systems with particular reference to the motion of vehicles on rough ground , 1986 .

[20]  Dean Karnopp,et al.  Vibration Control Using Semi-Active Force Generators , 1974 .

[21]  R. Leine,et al.  Bifurcations in Nonlinear Discontinuous Systems , 2000 .

[22]  P.J.Th. Venhovens,et al.  Investigation on Stability and Possible Chaotic Motions in the Controlled Wheel Suspension System , 1992 .

[23]  R S Sharp,et al.  The Relative Performance Capabilities of Passive, Active and Semi-Active Car Suspension Systems , 1986 .