Evaluation of Local Strain Distribution during Compressive Deformation of Open-Cell Porous Metals

Kazuya Maruyama; Xue Zheng Yue; Koichi Kitazono

doi:10.4028/www.scientific.net/MSF.933.169

Paper Titles

Theoretical Analysis of Porosity in an Ordered Porous Copper Fabricated by Continuous Unidirectional Solidification
p.136

Effects of Heat Treatment on Compressive Behavior of Porous Aluminum Manufactured by SLM
p.142

The Ordered Porous Aluminum: Modeling, Preparation, and Properties with Designed Structures
p.148

Thermal Conductivity Measurements of Novel Porous Copper Fiber Sintered Sheet
p.159

Evaluation of Local Strain Distribution during Compressive Deformation of Open-Cell Porous Metals
p.169

Microstructure and Compressive Properties of Al/Al₂O₃ Syntactic Foams
p.174

Observation of Gas Pores inside the Columnar Grains of a Lotus Type Porous Copper
p.182

The Dynamic Response of Sandwich Structures with Cellular Metallic Core under Blast Loading
p.188

The Compressive Properties of Open-Cell Zn-22Al Foams with Spheroidal Pore at Different Temperatures
p.196

HomeMaterials Science ForumMaterials Science Forum Vol. 933Evaluation of Local Strain Distribution during...

Evaluation of Local Strain Distribution during Compressive Deformation of Open-Cell Porous Metals

Abstract:

Relationship between the macroscopic and local strains of porous metals is examined by microstructural observation. Open-cell porous titanium with 60% porosity was compressed up to 30% macroscopic strain at room temperature. Open-cell porous nickel with 95% porosity was compressed up to 40% macroscopic strain at room temperature. Local strains in cell walls of both porous titanium and nickel were evaluated by electron backscatter diffraction (EBSD). Absolute value of the local strain increased with increasing the macroscopic strain and it is smaller than that of macroscopic strain. In addition, the value of the local strain at the cell junctions was larger than that of the center of cell struts.

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Periodical:

Materials Science Forum (Volume 933)

Pages:

169-173

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.933.169

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Online since:

October 2018

Authors:

Kazuya Maruyama, Xue Zheng Yue, Koichi Kitazono*

Keywords:

EBSD, Local Strain, Porous Nickel, Porous Titanium

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* - Corresponding Author

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