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MATERIALS SCIENCE
ArticleName Peculiarities of deformation and destruction of porous titanium nickelide alloys at stretching, compression and bending
DOI 10.17580/nfm.2022.02.12
ArticleAuthor Marchenko E. S., Baigonakova G. A., Garin A. S., Yasenchuk Yu. F.
ArticleAuthorData

National Research Tomsk State University, Tomsk, Russia:

E. S. Marchenko, Doctor of Physical and Mathematical Sciences, Associate Professor, Head of the Laboratory of Medical Alloys and Shape Memory Implants, e-mail: 89138641814@mail.ru
G. A. Baigonakova, Candidate of Physical and Mathematical Sciences, Assistant, Senior Researcher, e-mail: gat27@mail.ru
A. S. Garin, Post-Graduate Student, Research Engineer, e-mail: stik-020@mail.ru
Yu. F. Yasenchuk, Candidate of Physical and Mathematical Sciences, Associate Professor, Senior Researcher, e-mail: yayuri2008@gmail.com

Abstract

The analysis of experimental data obtained during quasi-static tension, compression and bending of anisotropic and structurally inhomogeneous porous titanium nickelide alloys obtained by the method of self-propagating high-temperature synthesis (SHS) is carried out. It is shown that the studied porous titanium nickelide alloy near room temperature is in a pre-martensitic state and experiences a reversible martensitic transformation (MT) under the action of an external load. The influence of geometric anisotropy on the deformation behavior under tension and bending is shown. By means of quasi-static tension and three-point bending to failure of lamellar samples of porous titanium nickelide with a porosity of 60–70%, it was shown for the first time that all obtained strain curves are qualitatively self-similar and contain a basic block of two linear hardening sections and a yield section between them. It is shown for the first time that a decrease in the effective cross section and a decrease in the degree of geometric anisotropy of the deformation zone lead to the appearance of an additional yield region on the deformation curves of quasi-static tension. This indicates a significant dependence of the contribution of reversible martensitic deformation to the total deformation on the geometric anisotropy of porous titanium nickelide. An analysis of fracture surfaces showed the effect of the type and rate of loading on the ratio of brittle martensitic and ductile austenite phases in a multiphase matrix of a porous titanium nickelide alloy.

The research was carried out with financial support of the Russian Science Foundation under the Grant No. 22-72-10037, https://rscf.ru/project/22-72-10037/.

keywords Titanium nickelide, high-temperature synthesis, deformation, martensitic transformation, superelasticity, shape memory effect
References

1. Shariat B. S., Liu Y., Rio G. Pseudoelastic Behaviour of Perforated NiTi Shape Memory Plates under Tension. Intermetallics. 2014. Vol. 50. pp. 59–64.
2. Melton K. N., Mercier O. The Mechanical Properties of NiTi-Based Shape Memory Alloys. Acta Metallurgica. 1981. Vol. 29, Iss. 2. pp. 393–398.
3. Shinkin V. N. Direct and Inverse Non-Linear Approximation of Hardening Zone of Steel. Chernye Metally. 2019. No. 3. pp. 32-37.
4. Peng W., Liu K., Shah B. A., Yuan B., Gao Y., Zhu M. Enhanced Internal Friction and Specific Strength of Porous TiNi Shape Memory Alloy Composite by the Synergistic Effect of Pore and Ti2Ni. Journal of Alloys and Compounds. 2020. Vol. 816. 152578.
5. Resnina N., Belyaev S., Voronkov A., Gracheva A. Mechanical Behaviour and Functional Properties of Porous Ti-45 at.% Ni Alloy Produced by Self-Propagating High-Temperature Synthesis. Smart Materials and Structures. 2016. Vol. 25, Iss. 5. 055018.
6. Yang B., Luo Z., Yuan B., Liu J., Gao Y. High Damping of Lightweight TiNi-Ti2Ni Shape Memory Composites for Wide Temperature Range Usage. Journal of Materials Engineering Performance. 2017. Vol. 26, Iss. 10. pp. 4970–4976.
7. Resnina N., Belyaev S. P., Voronkov A. Functional Properties of Porous Ti-48.0 at. % Ni Shape Memory Alloy Produced by Self-Propagating High Temperature Synthesis. Journal of Materials Engineering and Performance. 2018. Vol. 27, No. 3. pp. 1257–1264.
8. Zhang L., Zhang Y. Q., Jiang Y. H., Zhou R. Superelastic Behaviors of Biomedical Porous NiTi Alloy with High Porosity and Large Pore Size Prepared by Spark Plasma Sintering. Journal of Alloys and Compounds. 2015. Vol. 644. pp. 513–522.
9. Li B. Q., Wang C. Y., Lu X. Effect of Pore Structure on the Compressive Property of Porous Ti Produced by Powder Metallurgy Technique. Materials and Design. 2013. Vol. 50. pp. 613–619.
10. Otsuka K., Ren X. Physical Metallurgy of Ti-Ni-Based Shape Memory Alloys. Progress Materials Science. 2005. Vol. 50, No. 5. pp. 511–678.
11. Shinkin V. N. Springback Coefficient of Round Steel Beam Under Elastoplastic Torsion. CIS Iron and Steel Review. 2018. Vol. 15. pp. 23-27. DOI: 10.17580/cisisr.2018.01.05
12. Marchenko E. S., Yasenchuk Yu. F., Gunter S. V. et al. Viscoelastic Behavior of Biocompatible Titanium Nickelide Alloys. Tomsk: Tomsk State University, 2020. 102 p.
13. Yasenchuk Yu. F., Marchenko E. S., Baigonakova G. A. et al. Study on Tensile, Bending, Fatigue, and in vivo Behavior of Porous SHS-TiNi Alloy Used as a Bone Substitute. Biomedical Materials. 2021. Vol. 16, Iss. 2. 021001.
14. Marchenko E. S., Baigonakova G. A., Gunther V. E. Effect of Alloying of Titanium Nickelide-Based Alloys with Group V Elements (Vanadium, Niobium) on Their Mechanical Properties. Russian Metallurgy (Metally). 2018. No. 10. pp. 990-994.
15. Kornilov I. I., Belousov O. K., Kachur E. V. Titanium Nickelide and Other Alloys with the Effect of “Memory”. Moscow: Nauka, 1977. 179 p.
16. Marchenko E. S., Baigonakova G. A., Gunter V. E., Klopotov A. A. Martensitic Transformations in Alloys Based on Titanium Nickelide with Silver Additives. Novye Materialy i Tekhnologii. Barnaul: Altai State University, 2017. pp. 54-57.

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