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Structural and Multidisciplinary Optimization

Erschienen in:

11.03.2017 | INDUSTRIAL APPLICATION

Integrated design technique for materials and structures of vehicle body under crash safety considerations

verfasst von: Yuan Chen, Guiping Liu, Zheyi Zhang, Shujuan Hou

Erschienen in: Structural and Multidisciplinary Optimization | Ausgabe 2/2017

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Abstract

With the rapid development of the vehicle industry, crashworthiness has become a crucial aspect in vehicle body design. In fact, crashworthiness is a multivariable optimization design problem for a vehicle body, regardless of structure or material. However, when crashworthiness involves a large number of design variables, including both material and structure variables, it is more difficult to deal with. In this paper, an integrated design technique for materials and structures of vehicle body under crash safety consideration is suggested. First, a finite element model of the vehicle body is established according to relevant vehicle safety standards. Then, the material parameters of the vehicle body are set as analytical factors for factor screening. Next, significant factors are obtained using a three-level saturated design integrated with multi-index comprehensive balance analysis and the MaxUr ⁽³⁾ method, with an improved evaluation method. These screened material parameters along with the corresponding continuous variables of the structure, are considered as the design variables of the integrated design of the vehicle body. Both the weight and the crashworthiness properties are set as the design objectives. Optimal Latin hypercube sampling and radius basis functions are utilized to construct highly accurate surrogate models. Furthermore, the non-dominated sorting genetic algorithm II is implemented to seek the optimal solutions. Finally, two cases considering the roof module and the frontal module of a vehicle body are analyzed to verify the proposed method.

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Abramowitz M, Stegun IA (1972) Handbook of mathematical functions. National Bureau of Standards, Washington, D.CMATH

Bambach MR (2014) Fibre composite strengthening of thin steel passenger vehicle roof structures. Thin-Walled Struct 74(1–2):1–11CrossRef

Bathe KJ, Walczak J, Guillermin O, Bouzinov PA, Chen HY (1999a) Advances in crush analysis. Comput Struct 72(2):31–47CrossRefMATH

Bathe KJ, Walczak J, Guillermin O, Bouzinov PA, Chen HY (1999b) Advances in crush analysis. Comput Struct 72(1–3):31–47CrossRefMATH

Brian C, Petrinic G, Colin J (2008) Automotive engineering: lightweight, functional and novel materials. Taylor&Francis GROUP, New York

Chen X (2009) Optimization design of the structure of B-pillar based on roof crush and side impact analysis. Hunan University, Changsha

Chen Y, Kunert J (2004) A new quantitative method for analyzing unreplicated factorial designs. Biom J 46(2–3):125–140MathSciNetCrossRef

Chen Y, Chan CK, Leung BPK (2010) An analysis of three-level orthogonal saturated designs. Comput Stat Data Anal 54(2–5):1952–1961MathSciNetCrossRefMATH

Chuang CH, Yang RJ, Li G, Mallela K, Pothuraju P (2008) Multidisciplinary design optimization on vehicle tailor rolled blank design. Struct Multidiscip Optim 35:551–560CrossRef

Cui XT, Wang SX, Hu SJ (2008) A method for optimal design of automotive body assembly using multi-material construction. Mater Des 29(1–2):381–387CrossRef

Cui XT, Zhang HW, Wang SX, Zhang LH, Ko JH (2011) Design of lightweight multi-material automotive bodies using new material performance indices of thin-walled beams for the material selection with crashworthiness consideration. Mater Des 32(2):815–821CrossRef

Dobbertin MK, Freeman DM, Lambert EW, Lasarev RM, Kohles SS (2013) The relationship between vehicle roof crush and head, neck and spine injury in rollover crashes. Accid Anal Prev 58(1):46–52CrossRef

Duddeck F (2008) Multidisciplinary optimization of car bodies. Struct Multidiscip Optim 35(10–12):375–389CrossRef

Duddeck F, Heiserer D, Lescheticky J (2003) Stochastic methods for optimization of crash and NVH problems. In: Bathe KJ (ed) 2nd M.I.T. Conf. on Comput. Fluid and Solid Mech. Elsevier, Oxford, p 2265–2268

Dyn N, Levin D, Rippa S (1986) Numerical procedures for surface fitting of scattered data by radial basis functions. SIAM J Sci Stat Comput 7:639–659CrossRefMATH

Fang H, Rais-Rohani M, Liu Z, Horstmeyer MF (2005) A comparative study of metamodeling methods for multi-objective crashworthiness optimization. Comput Struct 83(4):21–36

Gu XG, Sun GY, Li GY, Mao LC, Li Q (2013) A comparative study on multiobjective reliable and robust optimization for crashworthiness design of vehicle structure. Struct Multidiscip Optim 48(3):669–684CrossRef

Hardy RL (1971) Multiquadratic equations of topography and other irregular surfaces. J Geophys Res 76:1905–1915CrossRef

Hou SJ, Li Q, Long SY, Yang XJ, Li W (2007) Design optimization of regular hexagonal thin-walled columns with crashworthiness criteria. Finite Elem Anal Des 43(2):555–565CrossRef

Hou SJ, Dong D, Ren LL, Han X (2012) Multivariable crashworthiness optimization of vehicle body by unreplicated saturated factorial design. 46(6): 891–905

Hou SJ, Liu TY, Dong D, Han X (2014a) Factor screening and multivariable crashworthiness optimization for vehicle side impact by factorial design. Struct Multidiscip Optim 49(8):147–167CrossRef

Hou SJ, Tan W, Zheng YN, Han X, Li Q (2014b) Optimization design of corrugated beam guardrail based on RBF-MQ surrogate model and collision safety consideration. Adv Eng Softw 78(4):28–40CrossRef

Hurnall J, Draheim A, Case M, Del Beato J (2003) A review of ‘B’-pillar and front seat belt loads measured in ANCAP offset frontal crash tests. In: Proceedings of 18th international technical conference on the enhanced safety of vehicles. Nagoya, Japan

Hvejsel CF, Lund E (2011) Material interpolation schemes for unified topology and multi-material optimization. Struct Multidiscip Optim 43(2):811–825CrossRefMATH

Jin R, Chen W, Simpson TW (2001) Comparative studies of metamodelling techniques under multiple modelling criteria. Struct Multidiscip Optim 23(1):1–13CrossRef

Jones N (1983) Impact crashworthiness. Int J Impact Eng 1(3):197CrossRef

Kiani M, Yildiz AR (2015) A comparative study of non-traditional methods for vehicle crashworthiness and NVH optimization. Arch Comput Methods Eng. doi:10.1007/s11831-015-9155-y MATH

Kodiyalam S, Yang JR, Gu L, Tho HC (2004) Multidisciplinary design optimization of a vehicle system in a scalable, high performance computing environment. Struct Multidiscip Optim 26(3–4):256–263CrossRef

Liao XT, Li Q, Yang XJ, Zhang WG, Li W (2008) Multiobjective optimization for crash safety design of vehicles using stepwise regression model. Struct Multidiscip Optim 35:561–569CrossRef

Liu GP, Han X, Jiang C (2008) A novel multi-objective optimization method based on an approximation model management technique. Comput Methods Appl Mech Eng 197(2):2719–2731CrossRefMATH

Lotus Engineering Inc (2010) An assessment of mass reduction opportunities for a 2017–2020 model year vehicle programme

Lu GX, Yu TX (2003) Energy absorption of structures and materials. WHP, EnglandCrossRef

Mallick PK (2010) Materials, design and manufacturing for lightweight vehicles. Woodhead Publishing, USACrossRef

Morris MD, Mitchell TJ (1995) Exploratory designs for computational experiments. J Stat Plan Infer 43(3):381–402CrossRefMATH

National Crash Analysis Center (NCAC) (2001) Public finite element model archive. www.ncac.gwu.edu/archives/model/index.html

NHTSA FMVSS 216 (2009) Final rule: federal motor vehicle safety standards; roof crush resistance. Docket No. NHTSA-2009-0093, RIN 2127-AG51. U.S. Government, Washington, DC

Ning HB, Pillay S, Vaidya UK (2009) Design and development of thermoplastic composite roof door for mass transit bus. Mater Des 30(1–2):983–991CrossRef

Pan F, Zhu P, Zhang Y (2010) Metalmodel-based lightweight design of B-pillar with TWB structure via support vector regression. Comput Struct 88(4):36–44CrossRef

Ramani A (2010) A pseudo-sensitivity based discrete-variable approach to structural topology optimization with multiple materials. Struct Multidiscip Optim 41(1):913–934CrossRef

Ramani A (2011) Multi-material topology optimization with strength constraints. Struct Multidiscip Optim 43(4):597–615CrossRef

Rowe J (2012) Advanced materials in automotive engineering. Woodhead Publishing Limited, UKCrossRef

Sobieszczanski-Sobieski J, Kodiyalam S, Yang RY (2001) Optimization of car body under constraints of noise, vibration, and harshness (NVH), and crash. Struct Multidiscip Optim 22(4):295–306CrossRef

Sun GY, Li GY, Zhou SW, Li HZ, Hou SJ, Li Q (2011) Crashworthiness design of vehicle by using multiobjective robust optimization. Struct Multidiscip Optim 44(5):99–110CrossRef

Taguchi G (1986) Introduction to quality engineering. Asian Productivity Organization, Tokyo

Tahan F, Digges K, Mohan P (2010) Sensitivity study of vehicle rollovers to various initial conditions finite element model based analysis. The National Crash Analysis Center

Tran T, Hou SJ, Han X, Chau M (2015) Crushing analysis and numerical optimization of angle element structures under axial impact loading. Compos Struct 119:422–435CrossRef

United Nations Economic Commission for Europe (1998) ECE R94:uniform provisions concerning the approval of vehicles with regard to the protection of the occupants in the event of a frontal collision

Zhao ZH, Han X, Jiang C, Zhou XX (2010) A nonlinear interval-based optimization method with local-densifying approximation technique. Struct Multidiscip Optim 42(3):559–573CrossRef

Zhu P, Pan F, Chen W, Zhang SL (2012) Use of support vector regression in structural optimization: application to vehicle crashworthiness design. Math Comput Simul 86(5):21–31MathSciNetCrossRef

Titel: Integrated design technique for materials and structures of vehicle body under crash safety considerations
verfasst von: Yuan Chen
Guiping Liu
Zheyi Zhang
Shujuan Hou
Publikationsdatum: 11.03.2017
Verlag: Springer Berlin Heidelberg
Erschienen in: Structural and Multidisciplinary Optimization / Ausgabe 2/2017
Print ISSN: 1615-147X
Elektronische ISSN: 1615-1488
DOI: https://doi.org/10.1007/s00158-017-1674-8

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