Finite element simulations on the mechanical properties of MHS materials 被引量：12

Finite element simulations on the mechanical properties of MHS materials

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摘要 Finite element simulations are carried out to examine the mechanical behavior of the metallic hollow sphere （MHS） material during their large plastic deformation and to estimate the energy absorbing capacity of these materials under uniaxial compression. A simplified model is proposed from experimental observations to describe the connection between the neighboring spheres, which greatly improves the computation efficiency. The effects of the governing physical and geometrical parameters are evaluated; whilst a special attention is paid to the plateau stress, which is directly related to the energy absorbing capacity. Finally, the empirical functions of the relative material density are proposed for the elastic modulus, yield strength and plateau stress for FCC packing arrangement of hollow spheres, showing a good agreement with the experimental results obtained in our previous study. Finite element simulations are carried out to examine the mechanical behavior of the metallic hollow sphere （MHS） material during their large plastic deformation and to estimate the energy absorbing capacity of these materials under uniaxial compression. A simplified model is proposed from experimental observations to describe the connection between the neighboring spheres, which greatly improves the computation efficiency. The effects of the governing physical and geometrical parameters are evaluated; whilst a special attention is paid to the plateau stress, which is directly related to the energy absorbing capacity. Finally, the empirical functions of the relative material density are proposed for the elastic modulus, yield strength and plateau stress for FCC packing arrangement of hollow spheres, showing a good agreement with the experimental results obtained in our previous study.

作者 Z. Y. Gao T. X. Yu D. Karagiozova

机构地区 Department of Mechanical Engineering Institute of Mechanics

出处《Acta Mechanica Sinica》 SCIE EI CAS CSCD 2007年第1期65-75,共11页 力学学报（英文版）

基金 The project supported by the Hong Kong Research Grant Council(RGC)(HKUST 6079/00E) the National Natural Science Foundation of China(10532020).

关键词 Cellular material Hollow sphere Large plastic deformation Numerical simulation FEM Cellular material Hollow sphere Large plastic deformation Numerical simulation FEM

分类号 TB383 [一般工业技术—材料科学与工程]

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参考文献12

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Finite element simulations on the mechanical properties of MHS materials 被引量：12

参考文献12

同被引文献58

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二级引证文献24

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