Temperature-Dependent Tension Plastic Deformation and Fracture Behavior of Ti-6.6Al-3.3Mo-1.8Zr-0.29Si Alloy at High Strain Rates-Reference-Cited by-同舟云学术

Temperature-Dependent Tension Plastic Deformation and Fracture Behavior of Ti-6.6Al-3.3Mo-1.8Zr-0.29Si Alloy at High Strain Rates

Published:2014-08 Issue: Volume:626 Page:115-120
ISSN:1662-9795
Container-title:Key Engineering Materials
language:
Short-container-title:KEM

Author:

Zhang Jun¹,Zhang Qi Wei¹,Wang Yang¹

Affiliation:

1. University of Science and Technology of China

Abstract

Titanium alloys have received great interest in the engineering applications requiring light weight and high impact resistance components. It is necessary to understand the mechanical properties of titanium alloys at high strain rates and various temperatures in the structural design. In the present paper, uniaxial tension tests at strain rates of 190, 500 and 1150s-1 and temperatures of 20, 150, 300°C are carried out using a modified split hopkinson tension bar system to investigate the effects of strain rate and temperature on tension behavior of the Ti-6.6Al-3.3Mo-1.8Zr-0.29Si alloy. Experimental results indicate that the alloy has the rate and temperature sensitivity and still keeps high strengths and toughness at temperature up to 300°C under high strain rate. SEM observations reveal that ductile fracture is the major fracture mode when the alloy is deformed at high strain rates.

Publisher

Trans Tech Publications, Ltd.

Subject

Mechanical Engineering,Mechanics of Materials,General Materials Science

Link

https://www.scientific.net/KEM.626.115.pdf

Reference17 articles.

1. M. Doner, and H. Conrad, Deformation Mechanisms in Commercial Ti (0. 5 At. Pct Oineq) at Intermediate and High Temperatures (0. 3 - 0. 6 Tinm), Metall. Trans. A, 4 (1973), 2809-17.

2. P. S. Follansbee, and G. T. Gray, An Analysis of the Low Temperature, Low and High Strain-Rate Deformation of Ti−6al−4v, Metall. Trans. A, 20 (1989), 863-74.

3. R. E. Reed-Hill, C. V. Iswaran, and M. J. Kaufman, An Analysis of the Flow Stress of a Two-Phase Alloy System, Ti-6al-4v, Metall. Mater. Trans. A, 27 (1996), 3957-62.

4. M. A. Greenfield, and H. Margolin, The Mechanism of Void Formation, Void Growth, and Tensile Fracture in an Alloy Consisting of Two Ductile Phases, Metall. Trans. A, 3 (1972), 2649-59.

5. A. Gysler, and G. Lütjering, Influence of Test Temperature and Microstructure on the Tensile Properties of Titanium Alloys, Metall. Trans. A, 13 (1982), 1435-43.