纳米结构钛的老化与力学性能研究

L. Rezyapova, R. Valiev, E. I. Usmanov, R. Valiev
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引用次数: 0

摘要

钛及其合金具有良好的生物相容性和耐腐蚀性,是工业上特别是医药上极具发展前景的材料之一。创伤学、骨科、牙科等最新的现代设备和仪器对材料的机械性能要求越来越高。与商业纯钛相比,合金不具有如此高的耐腐蚀性和生物相容性。在这方面,提高纯材料的机械特性是一个迫切的问题。研究了退火对工业纯4级钛粗晶态和超细晶态组织和性能的影响。采用高压扭转(HPT),在6 GPa的压力下,在N=10转的室温条件下获得了超细晶态。在透射电子显微镜下观察到退火后的析出相颗粒,它们具有不同的形貌。变形导致退火后析出颗粒增多。对α-相进行了x射线相分析,发现α-相在700℃变形退火后的晶格参数与纯钛的晶格参数接近。因此,在材料中发生老化过程,伴随着过饱和固溶体的分解和第二相颗粒的释放。本文给出了不同状态下钛的显微硬度测量结果。组合处理,包括N=5转的HPT, 700℃的退火,以及N=5转的额外HPT变形,可以获得商业纯4级钛的记录强度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
THE RESEARCH OF AGING AND MECHANICAL PROPERTIES OF NANOSTRUCTURAL TITANIUM
It is known that titanium and its alloys are one of the promising materials in the industry, especially in medicine, due to their excellent biocompatibility and corrosion resistance. The latest modern equipment and instruments used in traumatology, orthopedics, dentistry, etc. demand increasingly higher mechanical properties for materials. In comparison with commercially pure titanium, alloys do not have such high corrosion-resistant properties and biocompatibility. In this regard, improving the mechanical characteristics of a pure material is an urgent issue. The authors studied the effect of annealing on the structure and properties of commercially pure grade 4 titanium in the coarse-grained and ultrafine-grained states. The ultrafine-grained state was obtained using high-pressure torsion (HPT) under the pressure of 6 GPa at N=10 revolutions at room temperature. In the microstructure investigated using transmission electron microscopy, the authors could detect particles of precipitated phases after annealing, which had different morphologies. Deformation leads to an increase in the precipitated particles after annealing. The authors carried out an X-ray phase analysis, which showed the approximation of the lattice parameters of the α-phase after deformation and annealing at 700 °C to the values of the parameters of pure titanium. Thus, aging processes occur in the material, accompanied by the decomposition of the supersaturated solid solution and the release of particles of the second phase. The paper shows the results of titanium microhardness measurements in different states. The combined treatment, consisting of HPT at N=5 revolutions, annealing at 700 °C, and additional HPT deformation at N=5 revolutions, allowed obtaining the record strength for commercially pure grade 4 titanium.
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