超声诱导定向凝固三元铜-铝-镍合金的微结构转变并改善其力学性能

Y. J. Hu, J. Y. Wang, W. Zhai, B. Wei
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摘要

在 Cu68.3Al27.6Ni4.1 合金的定向凝固过程中引入了两种超声模式,即连续超声和脉冲超声。在连续超声场中,主β(Cu3Al)相发生了柱状到方形结构的转变,同时晶粒尺寸缩小了 7.5 倍。在脉冲超声下,β 相保持细柱状结构,晶粒大小相似。在前一种情况下,由于瞬态空化引起的大量局部过冷,在固/液(S/L)界面前形成了大量的 β 相成核点。同时,密集的声流将液体温度梯度从 120 K/cm 抑制到 85 K/cm,从而中断了溶质沿热流方向的迁移,形成了等轴微结构。在后一种情况下,在间歇性超声波作用下,S/L 接口附近产生的成核点较少,但在稳定的空化作用下,小的柱状 β 晶粒从原来的晶粒中分裂出来。由于没有驱动稳定的对流,110 K/cm 的液体温度梯度几乎保持不变,使得这些晶粒成长为精致的柱状结构。在脉冲超声的作用下,由于晶粒细化强化,屈服强度提高了 1.5 倍,同时由于柱状晶粒结构,形状恢复率达到 94%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Ultrasounds Induced Microstructure Transition and Improved Mechanical Property of Directionally Solidified Ternary Cu–Al–Ni Alloy

Ultrasounds Induced Microstructure Transition and Improved Mechanical Property of Directionally Solidified Ternary Cu–Al–Ni Alloy

Two ultrasonic modes, i.e., continuous and pulsed ultrasounds, were introduced into the directional solidification process of Cu68.3Al27.6Ni4.1 alloy. A columnar-to-equiaxed structure transition occurred to primary β(Cu3Al) phase within continuous ultrasonic field, which was accompanied with a grain size reduction by 7.5 times. Under pulsed ultrasound, β phase maintained the fine columnar structures with a similar grain size. In the former case, numerous β phase nucleation sites formed ahead of solid/liquid (S/L) interface because of the large local undercoolings induced by transient cavitation. Meanwhile, intensive acoustic streaming suppressed the liquid temperature gradient from 120 to 85 K/cm, which interrupted the solute transportation along heat flow direction and resulted in equiaxed microstructures. Under the intermittent ultrasonic action in the latter case, fewer nucleation sites were generated near S/L interface but small columnar β grains were split from the original ones under stable cavitation. Since no steady convection was driven, the liquid temperature gradient of 110 K/cm remained almost constant, making those grains grow into refined columnar structures. Under the action of pulsed ultrasound, the yield strength was enhanced by a factor of 1.5 because of grain refinement strengthening, together with 94 pct shape recovery rate due to columnar grain structures.

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