Title of article
Development of thermo-mechanical processing for fabricating highly durable -type Ti–Nb–Ta–Zr rod for use in spinal fixation devices
Author/Authors
Narita، نويسنده , , Kengo and Niinomi، نويسنده , , Mitsuo and Nakai، نويسنده , , Masaaki and Hieda، نويسنده , , Junko and Oribe، نويسنده , , Kazuya، نويسنده ,
Issue Information
ماهنامه با شماره پیاپی سال 2012
Pages
10
From page
207
To page
216
Abstract
The mechanical strength of a beta titanium alloy such as Ti–Nb–Ta–Zr alloy (TNTZ) can be improved significantly by thermo-mechanical treatment. In this study, TNTZ was subjected to solution treatment, cold caliber rolling, and cold swaging before aging treatment to form a rod for spinal fixation. The { 110 } β are aligned parallel to the cross-section with two strong peaks approximately 180 ∘ apart, facing one another, in the TNTZ rods subjected to cold caliber rolling and six strong peaks at approximately 60 ∘ intervals, facing one another, in the TNTZ rods subjected to cold swaging. Therefore, the TNTZ rods subjected to cold swaging have a more uniform structure than those subjected to cold caliber rolling. The orientation relationship between the α and β phases is different. A [ 110 ] β // [ 121 ] α , ( 112 ) β // ( 210 ) α orientation relationship is observed in the TNTZ rods subjected to aging treatment at 723 K after solution treatment and cold caliber rolling. On the other hand, a [ 110 ] β // [ 001 ] α , ( 112 ) β // ( 200 ) α orientation relationship is observed in TNTZ rod subjected to aging treatment at 723 K after cold swaging. A high 0.2% proof stress of about 1200 MPa, high elongation of 18%, and high fatigue strength of 950 MPa indicate that aging treatment at 723 K after cold swaging is the optimal thermo-mechanical process for a TNTZ rod.
Keywords
Biomaterials , Titanium alloys , Beta-type , Cord working , mechanical properties , Fatigue strength , Aging treatments , Spinal devices
Journal title
Journal of the Mechanical Behavior of Biomedical Materials
Serial Year
2012
Journal title
Journal of the Mechanical Behavior of Biomedical Materials
Record number
1405315
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