Metallurgical Abstracts on Light Metals and Alloys vol.54
Mechanical Property and Heat Treatment Behaviour of Ti-Zr-Fe Alloys
Chang Ting hsuan*, Maria Adachi**, Masato Ueda** and Masahiko Ikeda**
*Graduate School of Science and Engineering, Kansai University
**Faculty of Chemistry, Materials and Bioengineering, Kansai University
[Published in Materials Science Forum, Vol. 1016 (2021), pp. 1479–1484]
https://doi.org/10.4028/www.scientific.net/MSF.1016.1479
E-mail: m-ueda[at]kansai-u.ac.jp
Key Words:Titanium, Porous devices, 3D printing, Young’s modulus, Structural design
The element of zirconium (Zr) belongs to the same group 4 as Ti in the periodic table. Therefore it possesses similar chemical properties. The Ti-Zr binary system forms a continuous solid solution for both high temperature β phase with the body centered cubic (BCC) structure and low temperature α phase with the hexagonal close-packed (HCP) structure throughout the entire range of composition. As is well known, on the other hand, the element of iron (Fe) is not only inevitable but also effective element in Ti. By incorporating Fe at the stage of alloy design, off-grade sponge titanium can be employed. Both elements seem to be effective in strengthening the titanium alloys. The purpose of this work was to prepare Ti-Zr-Fe alloys and then mechanical property and heat treatment behaviours were investigated as a fundamental research. Ti-x mass% Zr-1mass% Fe alloys (x=0, 5, 10) were melted in a laboratory-scale arc furnace under a high purity argon atmosphere from the sponge Ti, the sponge Zr and the Fe wire. The resulting ingots were hot forged and rolled at approximately 1120 K to obtain plates of approximately 2 mm in thickness. Well-mixed and homogeneous samples could be obtained, oxygen contaminations were less than 0.09 %. Solid solution of Zr into Ti was confirmed by the XRD peak shift in α phase. Vickers hardness and proof stress increased with Zr content. No remarkable changes could be observed in the microstructures after the solution treatment at 1173 K. However, Young’s modulus increased at x=10 by the treatment.
The gradient ratio of α/α0 and 0.2% proof stress σ0.2 in Ti-Zr-Fe alloys depending on Zr content. Although the σ0.2 in as STQ increased with increasing Zr content, the α/α0 decreased.