Design of Ultra-Strong As-Cast Titanium Alloy at 600 ℃ by Using Cluster Formula

IF 2.9 2区材料科学 Q2 METALLURGY & METALLURGICAL ENGINEERING

Acta Metallurgica Sinica-English Letters Pub Date : 2024-10-12 DOI:10.1007/s40195-024-01778-x

Zhihao Zhu, Cenyang Wang, Tianyu Liu, Shuang Zhang, Chuang Dong

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Abstract

A Ti–5.4Al–6.4Zr–6.2Sn–0.4Mo–1.6W–0.4Nb–3.2Ta–0.5Si alloy is designed following cluster formula approach that achieves a strength level of 1 GPa at 600 ℃ in the as-cast state, superior to any existing high-temperature Ti alloys. Its composition is formulated by 17 basic units, α-{[Al-Ti₁₂](AlTi₂)}₁₂ + β-{[Al-Ti₁₂Zr₂](Mo_0.125Nb_0.125Ta_0.5W_0.25Sn_1.5Si_0.5)}₅, each unit covering a nearest-neighbor cluster plus a few next-neighbor glue atoms. This design is on the basis of the composition formula of Ti65 alloy, with an enhanced β stability via more Zr, Mo, Nb, Ta, W, Sn, and Si co-alloying. Upon copper-mold pour casting, this alloy shows a good microstructure stability. In tensile testing below at 650 ℃, its α plates thickness is nearly at the same level of 0.2 μm, which is much smaller than 0.7–0.8 μm of Ti65 at the same condition. The changes in volume fraction of β phase are increased by 86%, much less than by 105% in Ti65. Its room-temperature strength reaches the ultra-high-strength level, with an ultimate tensile strength of 1328 MPa and a yield strength of 1117 MPa, with a moderate elongation of 3.8%. At 600 ℃, its ultimate tensile strength of 1017 MPa and yield strength of 936 MPa are superior to those of any existing high-temperature Ti alloys, with an elongation of 7.2%. At 650 ℃, its ultimate tensile strength of 848 MPa still maintains a high level.

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利用簇式公式设计 600 ℃ 超强铸造钛合金

根据聚类公式法设计了一种钛-5.4Al-6.4Zr-6.2Sn-0.4Mo-1.6W-0.4Nb-3.2Ta-0.5Si 合金，在 600 ℃ 时的铸态强度达到 1 GPa，优于现有的任何高温钛合金。其成分由 17 个基本单元组成：α-{[Al-Ti12](AlTi2)}12 + β-{[Al-Ti12Zr2](Mo0.125Nb0.125Ta0.5W0.25Sn1.5Si0.5)}5，每个单元包括一个近邻原子团和几个近邻胶原子。这种设计以 Ti65 合金的成分式为基础，通过更多的 Zr、Mo、Nb、Ta、W、Sn 和 Si 共合金化来增强 β 稳定性。在铜模浇铸过程中，这种合金显示出良好的微观结构稳定性。在 650 ℃ 以下进行拉伸测试时，其 α 板厚度几乎保持在 0.2 μm 的水平，远小于相同条件下 Ti65 的 0.7-0.8 μm。β 相体积分数的变化增加了 86%，远小于 Ti65 的 105%。其室温强度达到超高强度水平，极限抗拉强度为 1328 兆帕，屈服强度为 1117 兆帕，伸长率为 3.8%。在 600 ℃ 时，其极限抗拉强度为 1017 兆帕，屈服强度为 936 兆帕，优于现有的任何高温钛合金，伸长率为 7.2%。在 650 ℃ 时，其极限抗拉强度仍保持在 848 兆帕的高水平。

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来源期刊

Acta Metallurgica Sinica-English Letters METALLURGY & METALLURGICAL ENGINEERING-

CiteScore

6.60

自引率

14.30%

发文量

122

审稿时长

2 months

期刊介绍： This international journal presents compact reports of significant, original and timely research reflecting progress in metallurgy, materials science and engineering, including materials physics, physical metallurgy, and process metallurgy.