Crashworthiness design of density-graded cellular metals 被引量：9

Crashworthiness design of density-graded cellular metals

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摘要 Crashworthiness of cellular metals with a linear density gradient was analyzed by using cell-based finite element models and shock models. Mechanisms of energy absorption and deformation of graded cellular metals were explored by shock wave propagation analysis. Results show that a positive density gradient is a good choice for protecting the impacting object because it can meet the crashworthiness requirements of high energy absorption, stable impact resistance and low peak stress. Crashworthiness of cellular metals with a linear density gradient was analyzed by using cell-based finite element models and shock models. Mechanisms of energy absorption and deformation of graded cellular metals were explored by shock wave propagation analysis. Results show that a positive density gradient is a good choice for protecting the impacting object because it can meet the crashworthiness requirements of high energy absorption, stable impact resistance and low peak stress.

作者 Xiaokai Wang Zhijun Zheng Jilin Yu

机构地区 CAS Key Laboratory of Mechanical Behavior and Design of Materials

出处《Theoretical & Applied Mechanics Letters》 CAS 2013年第3期9-13,共5页 力学快报（英文版）

基金 supported by the National Natural Science Foundation of China (90916026,11002140) the Fundamental Research Funds for the Central Universities(WK2090050023)

关键词 functionally graded materials deformation localization shock model CRASHWORTHINESS functionally graded materials, deformation localization, shock model, crashworthiness

分类号 TG14 [金属学及工艺—金属材料]

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参考文献14

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Theoretical & Applied Mechanics Letters

2013年第3期

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Crashworthiness design of density-graded cellular metals 被引量：9

参考文献14

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二级引证文献38

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