A physical model of polycrystalline Ni-Ti shape memory materials

Author

Zhang, Zhen ; Chen, C. ; Shen, Y.P.

Author_Institution

Beijing Univ. of Aeronaut. & Astronaut., China

Volume

1

fYear

2005

fDate

26-29 June 2005

Firstpage

153

Abstract

This paper derives a physical model for the polycrystalline shape memory alloys (SMAs) on the micromechanical basis. For the given materials, the model provides the link between the transformation behavior at the crystal-level and the details of the scalar behavior as stress-strain hysteresis loop and shape memory effect at the macroscopic level. The developed model has been applied to simulate the tension test of Ni-Ti alloy wire and the tension, compression and thin-walled tubular torsion test of Ni-Ti alloy. It is shown that the developed viscoplastic model can faithfully capture the key characteristic of observed hysteresis loop of shape memory alloys, and at the same time retains computational efficiency.

Keywords

crystal microstructure; intelligent materials; nickel alloys; shape memory effects; stress-strain relations; titanium alloys; Ni-Ti alloy wire; NiTi; compression test; crystal level transformation behavior; macroscopic shape memory effect; polycrystalline Ni-Ti shape memory materials; polycrystalline shape memory alloys; scalar behavior; stress-strain hysteresis loop; tension test; thin-walled tubular torsion test; viscoplastic model; Computational modeling; Crystalline materials; Crystals; Hysteresis; Micromechanical devices; Shape memory alloys; Testing; Thermal force; Thin wall structures; Wire;

fLanguage

English

Publisher

ieee

Conference_Titel

Control and Automation, 2005. ICCA '05. International Conference on

Print_ISBN

0-7803-9137-3

Type

conf

DOI

10.1109/ICCA.2005.1528108

Filename

1528108