Effects of Strain and Strain Rates on Microstructure Evolution Within ASB of TC4

IF 2 3区 工程技术 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Acta Mechanica Solida Sinica Pub Date : 2024-08-27 DOI:10.1007/s10338-024-00518-z
Qiang Zhou, Qilin Xiong, Zhaoquan Zeng
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Abstract

Adiabatic shear band (ASB), a typical failure mechanism in a metal at high strain rates, is hardly controllable or predictable to some extent. The development of the microstructure plays a crucial role in its formation. In this paper, the effect of strain rate on the development of microstructure in ASB of titanium alloy TC4 is investigated using hat-shaped specimens with the split-Hopkinson pressure bar device. The results show that the fracture strength of TC4 is significantly dependent on the shear strain rate. The increase in fracture strength from a strain rate of 11,300 s−1 to 24,930 s−1 is much higher than that from 24,930 s−1 to 35,620 s−1, which can be attributed to the effect of strain rate on dislocation evolution. Microstructures in both as-received and deformed states are investigated using various characterization techniques such as electron backscatter diffraction and X-ray diffraction. The region of ASB clearly shows three different microstructural features: random distribution of coarse grains (as received), distribution of elongated grains (transition zone), and distribution of equiaxed nanocrystals (shear-localized zone). The width of ASB increases with the strain rate. The possible reason for this is that the higher the strain rate, the larger the region where dynamic recrystallization (DRX) occurs due to the accumulation of a large number of dislocations. In the middle of ASB, a significant decrease in low-angle grain boundaries (LAGBs) and a large increase in high-angle grain boundaries are observed. The texture of specimens, especially the {11–20} and {10–10} planes, changes significantly during shear deformation at high strain rates. The mechanism of continuous dynamic recrystallization can well explain the formation and evolution of DRX within the ASB.

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应变和应变速率对 TC4 ASB 内部微观结构演变的影响
绝热剪切带(ASB)是金属在高应变速率下的一种典型失效机制,在一定程度上难以控制或预测。微观结构的发展对其形成起着至关重要的作用。本文利用劈裂-霍普金森压杆装置,使用帽形试样研究了应变速率对钛合金 TC4 ASB 中微观结构发展的影响。结果表明,TC4 的断裂强度与剪切应变速率有很大关系。应变速率从 11,300 秒-1 到 24,930 秒-1 时断裂强度的增加远高于应变速率从 24,930 秒-1 到 35,620 秒-1 时断裂强度的增加,这可归因于应变速率对位错演化的影响。利用电子反向散射衍射和 X 射线衍射等各种表征技术研究了接收状态和变形状态下的微观结构。ASB 区域清晰地显示出三种不同的微观结构特征:粗晶粒的随机分布(接收状态)、细长晶粒的分布(过渡区)和等轴纳米晶体的分布(剪切定位区)。ASB 的宽度随应变速率的增加而增加。其原因可能是应变速率越高,由于大量位错的积累而发生动态再结晶(DRX)的区域就越大。在 ASB 中期,观察到低角度晶界(LAGB)显著减少,而高角度晶界大量增加。试样的纹理,尤其是{11-20}和{10-10}面,在高应变率的剪切变形过程中发生了显著变化。连续动态再结晶机制可以很好地解释 ASB 内 DRX 的形成和演变。
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来源期刊
Acta Mechanica Solida Sinica
Acta Mechanica Solida Sinica 物理-材料科学:综合
CiteScore
3.80
自引率
9.10%
发文量
1088
审稿时长
9 months
期刊介绍: Acta Mechanica Solida Sinica aims to become the best journal of solid mechanics in China and a worldwide well-known one in the field of mechanics, by providing original, perspective and even breakthrough theories and methods for the research on solid mechanics. The Journal is devoted to the publication of research papers in English in all fields of solid-state mechanics and its related disciplines in science, technology and engineering, with a balanced coverage on analytical, experimental, numerical and applied investigations. Articles, Short Communications, Discussions on previously published papers, and invitation-based Reviews are published bimonthly. The maximum length of an article is 30 pages, including equations, figures and tables
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