ArticleName |
Influence of the size factor of titanium
nickelide alloy wire on structural characteristics and mechanical properties |
ArticleAuthorData |
Tomsk State University, Tomsk, Russia
S. V. Gunther, Senior Researcher, Candidate of Technical Sciences A. N. Monogenov, Senior Researcher, Candidate of Physical and Mathematical Sciences A. V. Vetrova, Research Engineer, Postgraduate Student, e-mail: aniuta-vetrova@mail.ru M. A. Kovaleva, Laboratory Assistant, Student |
Abstract |
The results of influence of the size factor on the structure, physical and mechanical properties of wire samples of alloys based on titanium nickelide are presented.Microstructur e analysis showed a direct dependence of strength properties on the average grain size. It is shown that as the wire diameter decreases from 3 to 0.04 mm, the average grain size decreases from 3 to 0.085 μm, respectively. Histograms of grain size distribution depending on the wire diameter from the alloy in question were constructed. The ratio of the volume of the oxide layer to the total volume of the wire increases with decreasing diameter of the wire samples and its influence intensifies. The size factor does not affect martensitic shear stress. Using X-ray microanalysis of the elemental composition, it was shown that the B2 phase, with a decrease in the diameter of the TiNi alloy wire from 3 to 0.04 mm, becomes depleted in titanium, which leads to an increase in the yield strength and, as a consequence, to higher mechanical characteristics. The tensile strength values were 670 and 1190 MPa for wires with a diameter of 3 and 0.04 mm, respectively. In the course of a comparative analysis of Vickers microhardness, an increase in microhardness (from 456 to 502 HV) was established depending on the diameter of the wire samples. The influence of the size factor on dissipative losses during martensitic transformations is a decrease in the width of the hysteresis loop with a decrease in the diameter of the wire made of an alloy based on titanium nickelide. The structure studies were carried out using the equipment of the Tomsk Regional Center for Collective Use of the National Research Tomsk State University. The center is supported by the Grant of the Ministry of Science and Higher Education of the Russian Federation No. 075-15-2021-693 (No. 13.TSKP.21.0012). The study was supported by a grant from the Russian Science Foundation (RSF), No. 19-72-10105, https://rscf.ru/project/19-72-10105/. |
References |
1. Chernyshova A., Kolomiets L., Chekalkin T. et al. Fertility-sparing surgery using knitted TiNi mesh implants and sentinel lymph nodes: A 10-year experience. J. Investig. Surg. 2021. Vol. 34. pp. 1110–1118. 2. Marandi L., Sen I. In-vitro mechanical behavior and high cycle fatigue characteristics of NiTi-based shape memory alloy wire. Int. J. Fatigue. 2021. Vol. 148. 106226. 3. Heller L., Seiner H., Šittner P., Sedlák P. et al. On the plastic deformation accompanying cyclic martensitic transformation in thermomechanically loaded NiTi. Int. J. Plast. 2018. Vol. 111. pp. 53–71. 4. Chen X., Shen Y., Fu S., Yu D. et al. Size effects on uniaxial tension and multiaxial ratcheting of oligo-crystalline stainless steel thin wires. Int. J. Fatigue. 2018. Vol. 116. pp. 163–171. 5. Gunther S., Chekalkin T., Kim Ji-soon et al. Impact of infrared on oxide layer of uitrathin TiNi-based alloy wire. Advanced Materials Letters. 2018. Vol. 9, Iss. 10. pp. 715–720. DOI: 10.5185/amlett.2018.1821 6. Medical materials and shape memory implants. In 14 vol. Shape memory implants in surgery. Vol. 1. Edited by V. E. Gunther. Tomsk, 2012. 398 p. 7. Frost M., Jury A., Heller L., Sedlak P. Experimentally validated constitutive model for NiTi-based shape memory alloys featuring intermediate R-phase transformation: A case study of Ni48Ti49Fe3. Materials and Design. 2021. Vol. 203. 109593. DOI: 10.1016/j.matdes.2021.109593 8. Muslov S. A. Elastic properties of metals and alloys before martensitic transformation. Mezhdunarodny nauchno-issledovatelskiy zhurnal. 2019. No. 2 (80). pp. 13–19. DOI: 10.23670/IRJ.2019.80.2.002 9. Monogenov A. N., Podoselnikova T. V., Kulbakin D. E. et al. Strength and plastic properties of thin wire made of TN-10 grade titanium nickelide. Izvestiya vuzov. Pfizika. 2014. Vol. 57. No. 6/2. pp. 79–83. 10. Marchenko E., Yasenchuk Yu., Vetrova A., Gunther S. Softening effect during cyclic stretching of titanium nickelide knitwear. Mekhanika kompozitsionnykh materialov i konstruktsiy. 2021. No. 27(4). pp. 459–481. DOI: 10.33113/mkmk.ras.2021.27.04.459_481.02 11. Waitz T., Antretter T., Fischer F. D., Karnthaler H. P. Size effects on martensitic phase transformations in nanocrystalline NiTi shape memory alloys. Material Science and Technology. 2008. Vol. 24. pp. 934–940. 12. Khmelevskaya I., Prokoshkin S., Brailovski V., Inaekyan K. et al. Functional properties of Ti – Ni-based shape memory alloys. Advanced in Science and Technology. 2008. Vol. 59. pp. 156–161. 13. Shi X., Cui L., Jiang D., Yu C. et al. Grain size effect on the R-phase transformation of nanocrystalline NiTi shape memory alloys. Journal of Material Science. 2014. Vol. 49. pp. 4643–4647. 14. Gunderov D., Lukyanov A., Prokofiev E., Kilmametov A. et al. Mechanical properties and martensitic transformations in nanocrystalline Ti49.4Ni50.6 alloy produced by high-pressure torsion. Material Science and Engineering A. 2009. Vol. 503. pp. 75–77. 15. Zhang X., Liu Q. Cu – Al – Ni – V high-temperature shape memory alloys. Intermetallics. 2018. Vol. 92. pp. 108–112. |