A multi-objective reliability-based optimization of the crashworthiness of a metallic-GFRP impact absorber using hybrid approximations

In the field of automotive safety, the lightweight design of crash absorbers is an important research topic with a direct effect on the occupant safety levels. The design of these absorbers usually requires an optimization of their crashworthiness, which can include multi-objective and reliability-b...

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Veröffentlicht in:	Structural and multidisciplinary optimization 2015-10, Vol.52 (4), p.827-843
Hauptverfasser:	Cid Montoya, M., Costas, M., Díaz, J., Romera, L. E., Hernández, S.
Format:	Artikel
Sprache:	eng
Schlagworte:	Absorbers Aluminum Computational Mathematics and Numerical Analysis Computer simulation Crashworthiness Design optimization Engineering Engineering Design Fiber reinforced polymers Finite element method Frontal impact Fuel consumption Glass fiber reinforced plastics Impact strength Industrial Application Multiple objective analysis Nonlinear response Optimization techniques Polymers Power consumption Reliability Response functions Safety Splines Statistical analysis Theoretical and Applied Mechanics Weight reduction
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creator	Cid Montoya, M. Costas, M. Díaz, J. Romera, L. E. Hernández, S.
description	In the field of automotive safety, the lightweight design of crash absorbers is an important research topic with a direct effect on the occupant safety levels. The design of these absorbers usually requires an optimization of their crashworthiness, which can include multi-objective and reliability-based optimization techniques. This process is very time-consuming, and in spite of the continuous growing of computational power, the problem needs a reliable solving scheme. The use of surrogate models and parallel computing are suitable alternatives to deal with this issue. However, the strongly non-linear response functions obtained from the finite element simulations need careful treatment. This work contributes with the application of a surrogate-based reliability-based design optimization method to an original design of a crash absorber made of metal and a glass-fiber reinforced polymer which is subjected to a frontal impact. Multi-adaptive regression splines models are employed to emulate the original responses, and three different approaches in the sampling stage of the method are compared. The absorbed energy and the mass of the element are considered as objective functions, while the peak value of the force transmitted to the occupants of the vehicle is the design constraint. A discussion of the employed materials is presented and the proposed approaches are compared. Finally, several Pareto fronts are obtained as a solution to the probabilistic problem. Results show that a combination of aluminum and glass fiber reinforced polymer is optimum for this problem, and some design rules are offered.
doi_str_mv	10.1007/s00158-015-1255-7
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E.</creatorcontrib><creatorcontrib>Hernández, S.</creatorcontrib><title>A multi-objective reliability-based optimization of the crashworthiness of a metallic-GFRP impact absorber using hybrid approximations</title><title>Structural and multidisciplinary optimization</title><addtitle>Struct Multidisc Optim</addtitle><description>In the field of automotive safety, the lightweight design of crash absorbers is an important research topic with a direct effect on the occupant safety levels. The design of these absorbers usually requires an optimization of their crashworthiness, which can include multi-objective and reliability-based optimization techniques. This process is very time-consuming, and in spite of the continuous growing of computational power, the problem needs a reliable solving scheme. The use of surrogate models and parallel computing are suitable alternatives to deal with this issue. However, the strongly non-linear response functions obtained from the finite element simulations need careful treatment. This work contributes with the application of a surrogate-based reliability-based design optimization method to an original design of a crash absorber made of metal and a glass-fiber reinforced polymer which is subjected to a frontal impact. Multi-adaptive regression splines models are employed to emulate the original responses, and three different approaches in the sampling stage of the method are compared. The absorbed energy and the mass of the element are considered as objective functions, while the peak value of the force transmitted to the occupants of the vehicle is the design constraint. A discussion of the employed materials is presented and the proposed approaches are compared. Finally, several Pareto fronts are obtained as a solution to the probabilistic problem. 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subjects	Absorbers Aluminum Computational Mathematics and Numerical Analysis Computer simulation Crashworthiness Design optimization Engineering Engineering Design Fiber reinforced polymers Finite element method Frontal impact Fuel consumption Glass fiber reinforced plastics Impact strength Industrial Application Multiple objective analysis Nonlinear response Optimization techniques Polymers Power consumption Reliability Response functions Safety Splines Statistical analysis Theoretical and Applied Mechanics Weight reduction
title	A multi-objective reliability-based optimization of the crashworthiness of a metallic-GFRP impact absorber using hybrid approximations
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