Title :
Crashworthiness and mass-reduction design of vehicles based on enhanced RSM
Author :
Chen Xiaokai ; Li Bangguo
Author_Institution :
Sch. of Mech. Eng., Beijing Inst. of Technol., Beijing, China
Abstract :
An enhanced response surface method (RSM) was formulated and evaluated with the optimization to increase vehicle full frontal crashworthiness and mass reduction. The impact finite element model was used for crashworthiness simulation in the nonlinear dynamics code, LS-DYNA. 8 design variables describing the thickness of the key structural components were chosen. 17 sets of sample points were gotten by optimal latin hypercubic method. With the simulation results, the surrogate models of acceleration peak value at B pillar and the components´ mass were built using the enhanced RSM. The crashworthiness and mass-reduction was optimized effectively based on the enhanced RSM.
Keywords :
design engineering; finite element analysis; impact testing; optimisation; response surface methodology; vehicle dynamics; LS-DYNA 8 design variables; crashworthiness simulation; enhanced RSM; impact finite element model; mass-reduction design; nonlinear dynamics code; optimal latin hypercubic method; vehicle design; Automotive engineering; Computational modeling; Design optimization; Equations; Finite element methods; Least squares approximation; Response surface methodology; Vehicle crash testing; Vehicle dynamics; Vehicles; Response Surface Method(RSM); crashworthiness; mass-reduction; optimization;
Conference_Titel :
Vehicle Power and Propulsion Conference, 2009. VPPC '09. IEEE
Conference_Location :
Dearborn, MI
Print_ISBN :
978-1-4244-2600-3
Electronic_ISBN :
978-1-4244-2601-0
DOI :
10.1109/VPPC.2009.5289697
