Multi-scale analyses of phase transformation mechanisms and hardness in linear friction welded Ti17(α + β)/Ti17(β) dissimilar titanium alloy joint

IF 5.3 1区 工程技术 Q1 ENGINEERING, AEROSPACE
Zhenguo GUO , Tiejun MA , Xiawei YANG , Ju LI , Wenya LI , Achilles VAIRIS
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引用次数: 0

Abstract

The Ti17(α + β)-Ti17(β) dual alloy-dual property blisk produced using Linear Friction Welding (LFW) is considered as high-performance component in advanced aeroengine. However, up to now, microstructure evolution and relationship between microstructure and micro mechanical properties of LFWed Ti17(α + β)/Ti17(β) dissimilar joint have not been thoroughly revealed. In this work, complex analyses of the phase transformation mechanisms of the joint are conducted, and phase transformations in individual zones are correlated to their microhardness and nanohardness. Results reveal that α dissolution occurs under high temperatures encountered during LFW, which reduces microhardness of the joint to that of Ti17(α + β) and Ti17(β). In Thermo-Mechanically Affected Zone of Ti17(α + β) (TMAZ-(α + β)) side joint, a large number of nanocrystalline α phases form with different orientations. This microstructure strengthens significantly by fine grains which balances partial softening effect of α dissolution, and increases nanohardness of α phase and microhardness of TMAZ-(α + β). Superlattice metastable β phase precipitates from metastable β in Weld Zone (WZ) during quick cooling following welding, because of short-range diffusion migration of solute atoms, especially β stabilizing elements Mo and Cr. The precipitation of the superlattice metastable β phase results in precipitation strengthening, which in turn increases nanohardness of metastable β and microhardness in WZ.

Ti17(α+β)/Ti17(β)异种钛合金线摩擦焊接接头相变机理及硬度的多尺度分析
采用线性摩擦焊接(LFW)技术生产的 Ti17(α + β)-Ti17(β)双合金-双性能叶盘被认为是先进航空发动机的高性能部件。然而,迄今为止,线性摩擦焊接 Ti17(α + β)/Ti17(β)异种接头的微观结构演变以及微观结构与微观机械性能之间的关系尚未得到深入揭示。本研究对接头的相变机制进行了复杂的分析,并将各区的相变与其显微硬度和纳米硬度相关联。结果表明,在低频熔化过程中遇到的高温下会发生α溶解,从而使接头的显微硬度降低到Ti17(α + β)和Ti17(β)的显微硬度。在 Ti17(α + β) 侧接头的热机械影响区(TMAZ-(α + β))中,形成了大量具有不同取向的纳米晶 α 相。这种微观结构通过细晶粒明显增强,平衡了 α 溶解的部分软化效应,提高了 α 相的纳米硬度和 TMAZ-(α+β)的显微硬度。由于溶质原子的短程扩散迁移,尤其是β稳定元素钼和铬的迁移,在焊接后快速冷却过程中,焊接区(WZ)中的可析出β相会从可析出β相中析出超晶格可析出β相。超晶格可转移 β 相的析出导致了析出强化,进而提高了可转移 β 的纳米硬度和 WZ 中的显微硬度。
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
Chinese Journal of Aeronautics
Chinese Journal of Aeronautics 工程技术-工程:宇航
CiteScore
10.00
自引率
17.50%
发文量
3080
审稿时长
55 days
期刊介绍: Chinese Journal of Aeronautics (CJA) is an open access, peer-reviewed international journal covering all aspects of aerospace engineering. The Journal reports the scientific and technological achievements and frontiers in aeronautic engineering and astronautic engineering, in both theory and practice, such as theoretical research articles, experiment ones, research notes, comprehensive reviews, technological briefs and other reports on the latest developments and everything related to the fields of aeronautics and astronautics, as well as those ground equipment concerned.
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