Effect of deformation processing on microstructure and mechanical properties of Ti-42Nb-7Zr alloy

IF 0.4 Q4 METALLURGY & METALLURGICAL ENGINEERING
A. Eroshenko, E. Legostaeva, I. Glukhov, P. Uvarkin, A. Tolmachev, N. Luginin, Vladimir Bataev, I. Ivanov, Y. Sharkeev
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Abstract

Introduction. The interest of modern medical materials science is focused on the development of beta-alloys of ternary systems (TNZ) based on titanium, niobium and zirconium with the low Young’s modulus, which is comparable with the elastic modulus of the bone. A wide application of the above alloys in medicine is limited by its insufficiently high strength properties, such as yield strength, ultimate strength, fatigue strength, fatigue life, etc. The formation of bulk ultrafine-grained structure in the alloys via deformation processing, including severe plastic deformation, ensures a considerable increase in the mechanical properties of alloys without toxic alloying elements. The aim of the work is to analyze the influence of deformation (multipass rolling and abc-pressing in combination with rolling) on the microstructure and mechanical properties of the alloy of the Ti-Nb-Zr system. The research methods. The Ti-42Nb-7Zr alloy cast blanks were made from pure titanium, niobium, and zirconium iodides by arc melting with a tungsten electrode in the protective argon atmosphere. It is shown that the cast blanks obtained have a high degree of uniformity in the distribution of niobium and zirconium alloying elements. To form an ultrafine-grained (UFG) structure, the cast blanks were subjected to deformation according to two schemes: 1) multipass rolling and 2) a combined method of severe plastic deformation, consisting in abc-pressing and subsequent multipass groove rolling. Results and discussion. As a result of deformation processing by rolling, an ultrafine-grained (UFG) structure is formed, which is represented by non-equiaxed -subgrains with cross-sectional dimensions 0.2…0.8 µm and length 0.2…0.7 µm, dispersion strengthened nanosized ω-phase, as well as subgrains of the -phase. Application of combined severe plastic deformation has promoted formation of a more dispersed UFG (+ω)-structure with an average size of structural elements equal to 0.3 μm. The UFG structure formed as a result of two-stage SPD has provided a high level of mechanical properties: yield strength – 480 MPa, ultimate strength – 1.100 MPa, microhardness – 2.800 MPa, with a low modulus of elasticity equal to 36 GPa.
变形处理对Ti-42Nb-7Zr合金组织和力学性能的影响
介绍。现代医学材料科学的兴趣集中在开发基于钛、铌和锆的三元体系β合金(TNZ),其杨氏模量低,可与骨的弹性模量相媲美。上述合金的屈服强度、极限强度、疲劳强度、疲劳寿命等强度性能不够高,限制了其在医学上的广泛应用。通过变形处理(包括剧烈的塑性变形)在合金中形成大块超细晶组织,确保了在不含有毒合金元素的情况下合金力学性能的显著提高。本文的目的是分析变形(多道次轧制和abc-pressing结合轧制)对Ti-Nb-Zr系合金组织和力学性能的影响。研究方法。以纯钛、铌、锆为原料,在保护氩气氛下用钨电极电弧熔化制备了Ti-42Nb-7Zr合金铸坯。结果表明,所得到的铸坯在铌锆合金元素的分布上具有高度的均匀性。为了形成超细晶组织,对铸坯进行了两种变形方案:1)多道次轧制和2)剧烈塑性变形的组合方法,即先进行abc压制,再进行多道次坡口轧制。结果和讨论。通过轧制变形处理,形成了一种超细晶(UFG)结构,其主要表现为截面尺寸为0.2 ~ 0.8µm、长度为0.2 ~ 0.7µm的非等轴-亚晶、弥散强化的纳米ω-相以及- ω-相亚晶。复合强塑性变形促进了更分散的UFG(+ω)结构的形成,其结构单元的平均尺寸为0.3 μm。两段SPD形成的UFG结构提供了高水平的机械性能:屈服强度- 480 MPa,极限强度- 1.100 MPa,显微硬度- 2.800 MPa,弹性模量低至36 GPa。
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来源期刊
Obrabotka Metallov-Metal Working and Material Science
Obrabotka Metallov-Metal Working and Material Science METALLURGY & METALLURGICAL ENGINEERING-
CiteScore
1.10
自引率
50.00%
发文量
26
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