Micromachining Imposed Subsurface Plastic Deformation in Single-Crystal Aluminum

Sudhanshu Nahata, M. Moradi, Y. Picard, N. Kota, O. B. Ozdoganlar
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引用次数: 7

Abstract

Abstract Mechanical removal of metal induces deformation and changes to microstructural characteristics of the newly created surfaces. The mode and extent of deformation can be difficult to predict since it depends on the local crystallographic orientation, which varies significantly for polycrystalline metals. In this work, we analyzed the deformation mode and extent beneath machined surfaces of different crystallographic orientations. This was accomplished by orthogonal micromachining of single-crystal aluminum along six different crystallographic orientations orthogonal to the sample [111] zone-axis, followed by electron backscatter diffraction (EBSD) analysis to evaluate the resulting subsurface microstructure and crystal lattice rotation. The results indicate that differences in the initial material crystallographic orientation produce significant variations in the depth of deformation (compared to the uncut chip thickness), the degree of grain refinement and the extent of lattice rotations. We grouped the orientation as “hard” or “soft” based on the measured cutting force. The soft orientations exhibit deformation modes consisting of shear bands and lattice rotations; whereas hard orientations exhibit deformation modes consistent with strain hardening: localized dynamic recrystallization, highly entangled dislocations and minimal crystal lattice rotations. The depth of subsurface deformation for some orientations was extensive, reaching depths far greater than the uncut chip thicknesses. Overall, we conclude that the cutting force required to machine a given orientation does provide some insight on the local deformation mode, and orientations can be easier or harder to machine based on local susceptibility to shear and lattice rotation.
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微加工对单晶铝表面下塑性变形的影响
机械去除金属会引起新生成表面的变形和微观结构特征的变化。变形的模式和程度很难预测,因为它取决于局部晶体取向,这对于多晶金属来说变化很大。在这项工作中,我们分析了不同晶体取向的加工表面下的变形模式和程度。这是通过沿着与样品[111]区轴正交的六个不同晶体取向对单晶铝进行正交微加工来完成的,然后通过电子背散射衍射(EBSD)分析来评估所得的地下微观结构和晶格旋转。结果表明,材料初始晶体取向的不同会导致变形深度(与未切割的切屑厚度相比)、晶粒细化程度和晶格旋转程度的显著变化。我们根据测量的切削力将方向分为“硬”或“软”。软取向表现出剪切带和晶格旋转的变形模式;而硬取向表现出与应变硬化一致的变形模式:局部动态再结晶,高度纠缠的位错和最小的晶格旋转。某些方向的地下变形深度非常广泛,其深度远远大于未切割的切屑厚度。总的来说,我们得出结论,加工给定方向所需的切削力确实提供了一些关于局部变形模式的见解,并且根据局部对剪切和晶格旋转的敏感性,方向可以更容易或更难加工。
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