Crushing analysis and multiobjective crashworthiness optimization of tapered square tubes under oblique impact loading

In this paper, a class of axisymmetric thin-walled square (ATS) tubes with two types of geometries (straight and tapered) and two kinds of cross-sections (single-cell and multi-cell) are considered as energy absorbing components under oblique impact loading. The crash behavior of the four types of ATS tubes, namely single-cell straight (SCS), single-cell tapered (SCT), multi-cell straight (MCS) and multi-cell tapered (MCT), are first investigated by nonlinear finite element analysis through LS-DYNA. It is found that the MCT tube has the best crashworthiness performance under oblique impact regarding both specific energy absorption (SEA) and peak crushing force (PCF). Sampling designs of the MCT tube are created based on a four-level full factorial design of experiments (DoE) method. Parametric studies are performed using the DoE results to investigate the influences of the geometric parameters on the crash performance of such MCT tubes under oblique impact loading. In addition, multiobjective optimization design (MOD) of the MCT tube is performed by adopting multiobjective particle swarm optimization (MOPSO) algorithm to achieve maximum SEA capacity and minimum PCF with and without considering load angle uncertainty effect. During the MOD process, accurate surrogate models, more specifically, response surface (RS) models of SEA and PCF of the MCT tubes are established to reduce the computational cost of crash simulations by finite element method. It is found that the optimal designs of the MCT tubes are different under different load angles. It is also found that the weighting factors for different load angles are critical in the MOD of the MCT tubes with load angle uncertainty.

[1]  Hasan Kurtaran,et al.  Crashworthiness design optimization using successive response surface approximations , 2002 .

[2]  S. Reid,et al.  Static and dynamic crushing of tapered sheet metal tubes of rectangular cross-section , 1986 .

[3]  Wei Li,et al.  Multiobjective optimization of multi-cell sections for the crashworthiness design , 2008 .

[4]  G. L. Viegelahn,et al.  Energy dissipation and associated failure modes when axially loading polygonal thin-walled cylinders , 1991 .

[5]  S. Park,et al.  Collapse behavior of square thin-walled columns subjected to oblique loads , 1999 .

[6]  T. Wierzbicki,et al.  Experimental and numerical studies of foam-filled sections , 2000 .

[7]  O. Hopperstad,et al.  Aluminum foam-filled extrusions subjected to oblique loading: experimental and numerical study , 2004 .

[8]  G. Wen,et al.  Crushing analysis and multiobjective crashworthiness optimization of honeycomb-filled single and bitubular polygonal tubes , 2011 .

[9]  Shutian Liu,et al.  Design optimization of cross-sectional configuration of rib-reinforced thin-walled beam , 2009 .

[10]  D. Thambiratnam,et al.  Dynamic simulation and energy absorption of tapered thin-walled tubes under oblique impact loading , 2006 .

[11]  Norman Jones,et al.  Dynamic progressive buckling of circular and square tubes , 1986 .

[12]  G. Cheng,et al.  A comparative study of energy absorption characteristics of foam-filled and multi-cell square columns , 2007 .

[13]  Ren-Jye Yang,et al.  Experience with approximate reliability-based optimization methods , 2003 .

[14]  F. Rammerstorfer,et al.  Experimental studies on the quasi-static axial crushing of steel columns filled with aluminium foam , 2000 .

[15]  Wei Li,et al.  Crashworthiness design for foam filled thin-wall structures , 2009 .

[16]  Zhiliang Tang,et al.  Energy absorption properties of non-convex multi-corner thin-walled columns , 2012 .

[17]  O. Hopperstad,et al.  Static and dynamic axial crushing of square thin-walled aluminium extrusions , 1996 .

[18]  Mark White,et al.  A theoretical analysis for the quasi-static axial crushing of top-hat and double-hat thin-walled sections , 1999 .

[19]  F. Rammerstorfer,et al.  Crushing of axially compressed steel tubes filled with aluminium foam , 1997 .

[20]  David P. Thambiratnam,et al.  Dynamic energy absorption characteristics of foam-filled conical tubes under oblique impact loading , 2010 .

[21]  Heung-Soo Kim,et al.  New extruded multi-cell aluminum profile for maximum crash energy absorption and weight efficiency , 2002 .

[22]  Qing Li,et al.  Design optimization of regular hexagonal thin-walled columns with crashworthiness criteria , 2007 .

[23]  E. Acar,et al.  Multi-objective crashworthiness optimization of tapered thin-walled tubes with axisymmetric indentations , 2011 .

[24]  Prospero C. Naval,et al.  An effective use of crowding distance in multiobjective particle swarm optimization , 2005, GECCO '05.

[25]  W. Abramowicz,et al.  Dynamic axial crushing of square tubes , 1984 .

[26]  Carlos A. Coello Coello,et al.  Handling multiple objectives with particle swarm optimization , 2004, IEEE Transactions on Evolutionary Computation.

[27]  G. Cheng,et al.  Theoretical prediction and numerical simulation of multi-cell square thin-walled structures , 2006 .

[28]  Yucheng Liu,et al.  Crashworthiness design of multi-corner thin-walled columns , 2008 .

[29]  Yucheng Liu,et al.  Optimum design of straight thin-walled box section beams for crashworthiness analysis , 2008 .

[30]  O. Hopperstad,et al.  Square aluminum tubes subjected to oblique loading , 2003 .

[31]  O. Hopperstad,et al.  Crashworthiness of aluminum extrusions subjected to oblique loading: experiments and numerical analyses , 2002 .

[32]  G. Lu,et al.  Quasi-static axial compression of thin-walled circular aluminium tubes , 2001 .

[33]  Kalyanmoy Deb,et al.  A fast and elitist multiobjective genetic algorithm: NSGA-II , 2002, IEEE Trans. Evol. Comput..

[34]  H. Zarei,et al.  Optimum honeycomb filled crash absorber design , 2008 .

[35]  J. M. Alexander AN APPROXIMATE ANALYSIS OF THE COLLAPSE OF THIN CYLINDRICAL SHELLS UNDER AXIAL LOADING , 1960 .

[36]  David P. Thambiratnam,et al.  A numerical study on the impact response and energy absorption of tapered thin-walled tubes , 2004 .

[37]  Panos Y. Papalambros,et al.  Principles of Optimal Design: Modeling and Computation , 1988 .

[38]  David W. Corne,et al.  Approximating the Nondominated Front Using the Pareto Archived Evolution Strategy , 2000, Evolutionary Computation.

[39]  O. Hopperstad,et al.  Static and dynamic crushing of square aluminium extrusions with aluminium foam filler , 2000 .

[40]  Xu Han,et al.  Multiobjective optimization for tapered circular tubes , 2011 .

[41]  Douglas C. Montgomery,et al.  Response Surface Methodology: Process and Product Optimization Using Designed Experiments , 1995 .

[42]  M. Kröger,et al.  Bending behavior of empty and foam-filled beams: Structural optimization , 2008 .

[43]  H. Zarei,et al.  Experimental and numerical crashworthiness investigation of empty and foam-filled end-capped conical tubes , 2011 .

[44]  T. Wierzbicki,et al.  On the Crushing Mechanics of Thin-Walled Structures , 1983 .

[45]  A. Toksoy,et al.  Quasi-static axial crushing of extruded polystyrene foam-filled thin-walled aluminum tubes: Experimental and numerical analysis , 2006 .

[46]  David P. Thambiratnam,et al.  Computer simulation and energy absorption of tapered thin-walled rectangular tubes , 2005 .

[47]  H. R. Zarei,et al.  Optimization of the foam-filled aluminum tubes for crush box application , 2008 .

[48]  T. Wierzbicki,et al.  Relative merits of single-cell, multi-cell and foam-filled thin-walled structures in energy absorption , 2001 .