Enhanced strength-ductility synergy in Ti-4Al-5Mo-5V-5Cr-1Nb with hierarchical microstructure

IF 2.2 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Materials Letters: X Pub Date : 2022-12-01 DOI:10.1016/j.mlblux.2022.100168

T. Wang , F. Yong , X.H. Liu , K.X. Wang , Y.X. Du , F. Zhao

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引用次数: 1

Abstract

In general, metastable β-Ti-alloys exhibit low ductility at room temperature, which restricts its workability and critical applications. Here, we report a hierarchical microstructure tailoring strategy to achieve an excellent strength-ductility combination in Ti-4Al-5Mo-5V-5Cr-1Nb (Ti-45551) alloy. It was revealed that high density deformation twinning can be successfully introduced in primary α particles of Ti-45551 alloy through warm dynamic plastic deformation (DPD). After warm DPD process, the hierarchical microstructure was constructed in Ti-45551 alloy, including equiaxed primary α particles with high density deformation twins, β-phase matrix and finely dispersed nanoscale secondary α lamellas. Uniaxial tensile experiments have revealed that Ti-45551 alloy exhibited enhanced strength-ductility synergy with hierarchical microstructure at room temperature. This excellent combination of strength and ductility is derived from high twin density in in primary α particles and unique hierarchical microstructure. Also, this study demonstrates a feasible and low-cost route to design high performance Ti alloy.

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Ti-4Al-5Mo-5V-5Cr-1Nb中增强的强度-塑性协同作用

一般来说，亚稳态β- ti合金在室温下具有较低的延展性，这限制了其可加工性和关键应用。在这里，我们报告了一种分层显微组织定制策略，以实现Ti-4Al-5Mo-5V-5Cr-1Nb (Ti-45551)合金的优异强度-塑性组合。结果表明，通过热动态塑性变形(DPD)可以成功地在Ti-45551合金的初生α粒子中引入高密度变形孪晶。高温DPD处理后，Ti-45551合金形成了具有高密度变形孪晶的等轴初生α颗粒、β相基体和分散的纳米级次级α片层等层次组织。单轴拉伸实验表明，室温条件下，Ti-45551合金的强度-塑性协同效应随着分层组织的增加而增强。这种优异的强度和延展性的结合源于高孪晶密度的初生α颗粒和独特的分层组织。同时，本研究也为设计高性能钛合金提供了一条可行的低成本途径。

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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