Strength and fracture mechanism of a magnesium alloy for medical applications after equal-channel angular pressing

G.V. Klevtsov, R.Z. Valiev, N.A. Klevtsova, M.V. Fesenyuk ORCID logo , O.B. Kulaysova ORCID logo , I.N. Pigaleva показать трудоустройства и электронную почту
Получена 18 марта 2022; Принята 06 июня 2022;
Эта работа написана на английском языке
Цитирование: G.V. Klevtsov, R.Z. Valiev, N.A. Klevtsova, M.V. Fesenyuk, O.B. Kulaysova, I.N. Pigaleva. Strength and fracture mechanism of a magnesium alloy for medical applications after equal-channel angular pressing. Письма о материалах. 2022. Т.12. №3. С.203-208
BibTex   https://doi.org/10.22226/2410-3535-2022-3-203-208

Аннотация

Typical view of the "Torque - angle of twist" diagrams during the torsion test of specimens with a diameter of 3 mm made from magnesium alloy Mg-Zn-Ca after annealing (1) and after ECAP (2)In this paper, we study the strength and fracture mechanism of the cast magnesium alloy Mg-Zn-Ca (1.0 % Zn, 0.2 % Ca) for medical applications after equal-channel angular pressing (ECAP) in comparison with the initial condition (after homogenization annealing). Mechanical tests included tensile and torsion tests of samples with a diameter of 3 mm and impact strength tests of samples with a V-shaped stress raiser. The microrelief of all fractures was studied in a Phenom ProX G6 scanning electron microscope (SEM). The results of tensile testing of the samples showed that the strength of the alloy after ECAP increased by a factor of 1.5 –1.8, and the elongation increased by a factor 2.6. The torsional strength of the alloy increased by a factor 1.1–1.3, and the relative shear of the alloy decreased by factor a 1.3 as compared with the alloy after annealing. In contrast to static loads, the magnesium alloy Mg-Zn-Са after ECAP is poorly resisting one-time impact loads. Analysis of the results of this study allows us to conclude that the magnesium alloy Mg-Zn-Ca after ECAP is more promising for the manufacture of medical products that experience static loads during operation, as compared with the alloy after annealing.

Ссылки (25)

1. J. S. Hayes, R. G. Richards. Osseointegration of permanent and temporary orthopedic implants. In: Encyclopedia of Biomedical Engineering (Ed. by R. Narayan). Elsevier, Amsterdam, Netherlands (2019) pp. 257 - 269. Crossref
2. I. P. Semenova, G. N. Klevtsov, N. A. Klevtsova, G. S. Dyakonov, A. A. Matchin, R. Z. Valiev. Adv. Eng. Mater. 18, 1216 (2016). Crossref
3. A. V. Bondarenko, E. A. Raspopova, V. A. Peleganchuk. Bulletin of Traumatology and Orthopedics n. a. N. N. Priorov. 2, 41 (2004). (in Russian) [А. В. Бондаренко, Е. А. Распопова, В. А. Пелеганчук. Вестник травматологии и ортопедии им. Н. Н. Приорова. 2, 41 (2004).]. Crossref
4. T. Fujishiro, D. J. Moojen, N. Kobayashi, W. J. Dhert, T. W. Bauer. Clin. Orthop. Relat. Res. 469, 1127 (2011). Crossref
5. S. N. Meisner, M. V. Kotenko, V. A. Kopysova, A. I. Yaremenko, I. K. Ratkin. Zabaikalsky Medical Bulletin. 1, 59 (2016). (in Russian) [С. Н. Мейснер, М. В. Котенко, В. А. Копысова, А. И. Яременко, И. К. Раткин. Забайкальский медицинский вестник. 1, 59 (2016).].
6. G. V. Klevtsov, R. Z. Valiev, N. A. Klevtsova, M. N. Tyurkov, M. L. Linderov, M. M. Abramova, A. G. Raab, T. B. Minasov. Materials. 14, 7739 (2021). Crossref
7. R. Z. Valiev, A. P. Zhilyaev, T. G. Langdon. Bulk Nanostructured Materials: Fundamentals and Applications. John Wiley & Sons, Hoboken, NJ, USA (2014) 440 р. Crossref
8. Y. M. Wang, E. Ma. Acta Materialia. 52 (6), 1699 (2004). Crossref
9. I. A. Ovid’ko, T. G. Langdon. Reviews on Advanced Materials Sci. 30, 11 (2012).
10. Y. Estrin, A. Vinogradov. International Journal of Fatigue. 32, 898 (2010). Crossref
11. H. Mughrabi, H. W. Hoppel, M. Kautz. Scripta Materialia. 51, 807 (2004). Crossref
12. L. W. Meyer, K. Sommer, T. Halle, M. Hockauf. Materials Science Forum. 584 - 586, 815 (2008). Crossref
13. G. V. Klevtsov, R. Z. Valiev, N. A. Klevtsova, O. B. Kulyasova, E. D. Merson, M. L. Linderov, A. V. Ganeev. Letters on Materials. 10 (4), 398 (2020). (in Russian) [Г. В. Клевцов, Р. З. Валиев, Н. А. Клевцова, О. Б. Кулясова, Е. Д. Мерсон, М. Л. Линдеров, А. В. Ганеев. Письма о материалах. 10 (4), 398 (2020).]. Crossref
14. I. A. Ovid’ko, R. Z. Valiev, Y. T. Zhu. Progress in Materials Science. 94, 462 (2018). Crossref
15. G. V. Klevtsov, R. Z. Valiev, N. A. Klevtsova, M. V. Fesenyuk, M. N. Tyurkov, A. V. Polyakov. Letters on Materials. 11 (3), 273 (2021). (in Russian) [Г. В. Клевцов, Р. З. Валиев, Н. А. Клевцова, М. В. Фесенюк, М. Н. Тюрьков, А. В. Поляков. Письма о материалах. 11 (3), 273 (2021).]. Crossref
16. A. Vinogradov, E. Vasilev, V. Kopylov, M. Linderov, A. Brilevesky, D. Merson. Metals. 9 (2), 186 (2019). Crossref
17. E. Vasilev, M. Linderov, D. Nugmanov, O. Sitdikov, M. Markushev, A. Vinogradov. Metals. 5 (4), 2316 (2015). Crossref
18. E. V. Vasilev, V. I. Kopylov, M. L. Linderov, А. I. Brilevsky, D. L. Merson, A. Yu. Vinogradov. Letters on Materials. 9 (2), 157 (2019). Crossref
19. D. Merson, A. Brilevsky, P. Myagkikh, A. Tarkova, A. Prokhorikhin, E. Kretov, T. Frolova, A. Vinogradov. Materials. 13 (3), 544 (2020). Crossref
20. M. Linderov, A. Brilevsky, D. Merson, A. Danyuk, A. Vinogradov. Materials. 15 (2), 567 (2022). Crossref
21. D. Merson, M. Linderov, A. Brilevsky, A. Danyuk, A. Vinogradov. Materials. 15 (1), 328 (2022). Crossref
22. G. V. Klevtsov, L. R. Botvina, N. A. Klevtsova, L. V. Limar. Fractodiagnosis of the Fracture of Metallic Materials and Structures. Moscow, MISiS (2007) 264 p. (in Russian) [Г. В. Клевцов, Л. Р. Ботвина, Н. А. Клевцова, Л. В. Лимарь. Фрактодиагностика разрушения металлических материалов и конструкций. Москва, МИСиС (2007) 264 с.].
23. V. S. Zolotarevskii. Mekhanicheskie svoistva metallov. Moscow, MISiS (1998) 400 р. (in Russian) [В. С. Золоторевский. Механические свойства металлов. Москва, МИСИС (1998) 400 с.].
24. N. Martynenko, N. Anisimova, M. Kiselevsky, N. Tabachkova, D. Temralieva, D. Prosvirnin, V. Terentiev, A. Koltygin, V. Belov, M. Morozov, V. Yusupov, S. Dobatkin, Y. Estrin. Journal of Magnesium and Alloys. 8, 1038 (2020). Crossref
25. S. V. Dobatkin, E. A. Lukyanova, N. S. Martynenko, N. Yu. Anisimova, M. V. Kiselevskiy, M. V. Gorshenkov, N. Yu. Yurchenko, G. I. Raab, V. S. Yusupov, N. Birbilis, G. A. Salishchev, Y. Z. Estrin. IOP Conf. Series: Materials Science and Engineering. 194, 012004 (2017). Crossref

Другие статьи на эту тему

Финансирование на английском языке

1. Российский научный фонд - 20-69-47059
2. Российский научный фонд - 20-63-47027