Failure behavior of cellular titanium under dynamic loading

Hui Lan Ren; Jing Wang; Li Hao; Hai Ting Shen

doi:10.1007/s11431-017-9014-4

Failure behavior of cellular titanium under dynamic loading

Hui Lan Ren, Jing Wang, Li Hao^*, Hai Ting Shen

^*Corresponding author for this work

School of Mechatronical Engineering

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

The dynamic compressive deformation of cellular titanium with regularly distributed cylindrical pores is investigated to evaluate the effect of shock attenuation and obtain the shock Hugoniot relationship of the material. Dynamic compression experiments are conducted at room temperature using a single-stage light gas gun. The Hugoniot relations between shock wave velocity and particle velocity for the cellular titanium samples with porosities 20% and 30% are obtained. The shock response of the regular cellular titanium shows a clear wave attenuation effect. Numerical simulations are also conducted to supplement the experimental study. Inelastic deformation is observed in the samples using optical micrographs, indicating that the deformation of pores contributes significantly to the shock wave attenuation of the cellular titanium material.

Original language	English
Pages (from-to)	613-623
Number of pages	11
Journal	Science China Technological Sciences
Volume	60
Issue number	4
DOIs	https://doi.org/10.1007/s11431-017-9014-4
Publication status	Published - 1 Apr 2017

Keywords

Hugoniot relation
cellular titanium
dynamic compression
plate impact

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10.1007/s11431-017-9014-4

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title = "Failure behavior of cellular titanium under dynamic loading",

abstract = "The dynamic compressive deformation of cellular titanium with regularly distributed cylindrical pores is investigated to evaluate the effect of shock attenuation and obtain the shock Hugoniot relationship of the material. Dynamic compression experiments are conducted at room temperature using a single-stage light gas gun. The Hugoniot relations between shock wave velocity and particle velocity for the cellular titanium samples with porosities 20% and 30% are obtained. The shock response of the regular cellular titanium shows a clear wave attenuation effect. Numerical simulations are also conducted to supplement the experimental study. Inelastic deformation is observed in the samples using optical micrographs, indicating that the deformation of pores contributes significantly to the shock wave attenuation of the cellular titanium material.",

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AU - Ren, Hui Lan

AU - Wang, Jing

AU - Hao, Li

AU - Shen, Hai Ting

PY - 2017/4/1

Y1 - 2017/4/1

N2 - The dynamic compressive deformation of cellular titanium with regularly distributed cylindrical pores is investigated to evaluate the effect of shock attenuation and obtain the shock Hugoniot relationship of the material. Dynamic compression experiments are conducted at room temperature using a single-stage light gas gun. The Hugoniot relations between shock wave velocity and particle velocity for the cellular titanium samples with porosities 20% and 30% are obtained. The shock response of the regular cellular titanium shows a clear wave attenuation effect. Numerical simulations are also conducted to supplement the experimental study. Inelastic deformation is observed in the samples using optical micrographs, indicating that the deformation of pores contributes significantly to the shock wave attenuation of the cellular titanium material.

AB - The dynamic compressive deformation of cellular titanium with regularly distributed cylindrical pores is investigated to evaluate the effect of shock attenuation and obtain the shock Hugoniot relationship of the material. Dynamic compression experiments are conducted at room temperature using a single-stage light gas gun. The Hugoniot relations between shock wave velocity and particle velocity for the cellular titanium samples with porosities 20% and 30% are obtained. The shock response of the regular cellular titanium shows a clear wave attenuation effect. Numerical simulations are also conducted to supplement the experimental study. Inelastic deformation is observed in the samples using optical micrographs, indicating that the deformation of pores contributes significantly to the shock wave attenuation of the cellular titanium material.

KW - Hugoniot relation

KW - cellular titanium

KW - dynamic compression

KW - plate impact

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JO - Science China Technological Sciences

JF - Science China Technological Sciences

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ER -

Failure behavior of cellular titanium under dynamic loading

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