The Structure and Mechanical Properties of Ti–(36–40)Zr–9Ta (at %) Alloys for Medical Purposes

IF 0.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Inorganic Materials: Applied Research Pub Date : 2024-10-09 DOI:10.1134/S2075113324700941

M. A. Volchikhina, S. V. Konushkin, S. A. Mikhlik, K. V. Sergienko, M. A. Kaplan, A. D. Gorbenko, T. M. Sevostyanova, A. G. Kolmakov, M. A. Sevostyanov

引用次数: 0

Abstract

In this work, the following are investigated: structure, phase composition and mechanical properties under static tension of titanium alloys Ti–(36–40)Zr–9Ta (at %) for medical use after hot rolling and quenching. After rolling, the alloys consist of α'- and β-phases. The results of the research show that the hardening of alloys leads to the almost complete dissolution of the β-phase and the release of α'- and α"-phases. Investigations of mechanical properties of alloys Ti–(36–40)Zr–9Ta (at %) show that, in terms of tensile strength, the studied alloys Ti–36Zr–9Ta, Ti–38Zr–9Ta, and Ti–40Zr–9Ta are similar to the VT6 alloy widely used for implants (σ = 835–1100 MPa), and, in terms of plasticity (δ = 15–21%) and low value of Young’s modulus (E = 53–73 GPa), significantly exceeds it.

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医用 Ti-(36-40)Zr-9Ta (%) 合金的结构和机械性能

在这项工作中，研究了以下内容：热轧和淬火后的医用钛合金 Ti-(36-40)Zr-9Ta (%)的结构、相组成和静态拉伸下的机械性能。轧制后的合金由 α'- 和 β - 相组成。研究结果表明，合金硬化导致 β 相几乎完全溶解，并释放出 α'- 和 α"-相。对合金 Ti-(36-40)Zr-9Ta （%）机械性能的研究表明，就抗拉强度而言，所研究的合金 Ti-36Zr-9Ta、Ti-38Zr-9Ta 和 Ti-40Zr-9Ta 与广泛用于植入物的 VT6 合金相似（σ = 835-1100 MPa），而就塑性（δ = 15-21%）和杨氏模量的低值（E = 53-73 GPa）而言，则大大超过了 VT6 合金。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Inorganic Materials: Applied Research Engineering-Engineering (all)

CiteScore

0.90

自引率

0.00%

发文量

199

期刊介绍： Inorganic Materials: Applied Research contains translations of research articles devoted to applied aspects of inorganic materials. Best articles are selected from four Russian periodicals: Materialovedenie, Perspektivnye Materialy, Fizika i Khimiya Obrabotki Materialov, and Voprosy Materialovedeniya and translated into English. The journal reports recent achievements in materials science: physical and chemical bases of materials science; effects of synergism in composite materials; computer simulations; creation of new materials (including carbon-based materials and ceramics, semiconductors, superconductors, composite materials, polymers, materials for nuclear engineering, materials for aircraft and space engineering, materials for quantum electronics, materials for electronics and optoelectronics, materials for nuclear and thermonuclear power engineering, radiation-hardened materials, materials for use in medicine, etc.); analytical techniques; structure–property relationships; nanostructures and nanotechnologies; advanced technologies; use of hydrogen in structural materials; and economic and environmental issues. The journal also considers engineering issues of materials processing with plasma, high-gradient crystallization, laser technology, and ultrasonic technology. Currently the journal does not accept direct submissions, but submissions to one of the source journals is possible.