Shear strain induced formation of nanostructured pure metals

Q4 Engineering

International Journal of Nanoparticles Pub Date : 2009-06-17 DOI:10.1504/IJNP.2008.026470

M. Jackson, J. Morrell, W. Ahmed

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引用次数: 0

Abstract

Chip formation is of fundamental importance during the formation of nanostructured pure metals. Poor chip control leads to chip build-up and an uncontrollable surface roughness. The use of chip breaking is arbitrary because of the mechanics of chip curl is not well understood. The causes of chip curl and chip flow are still the subject of intense discussion and research among plasticity researchers. The subject originally focused on cutting forces and on the conditions at the chip-tool interface using soft plastic metals. The increasing speed of cutting has focused researchers to look at chip breaking after the chip has been cut. In the first instance, chips were considered to be continuous, discontinuous and continuous with a built-up edge. The theories of metal cutting allow one to predict the forces and stresses in the chip during formation but do not tell us anything about the strain within the chip, unless a computational approach is used. This paper describes the mechanics of chip formation using the grinding process at the microscale and explains how the deformation of the grinding grains affects shear strain rates and the average grain size in the cut chip.

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剪切应变诱导纳米结构纯金属的形成

在纳米结构纯金属的形成过程中，晶片的形成是至关重要的。不良的芯片控制导致芯片堆积和不可控的表面粗糙度。由于对切屑卷曲的机制还没有很好地理解，所以切屑断裂的使用是任意的。切屑卷曲和切屑流动的原因一直是塑性研究人员讨论和研究的热点。该主题最初集中在切削力和条件在切屑-刀具界面使用软塑料金属。随着切割速度的提高，研究人员开始关注切屑切割后的断裂情况。在第一种情况下，芯片被认为是连续的，不连续的和连续的，并有一个累积的边缘。金属切削理论允许人们预测切屑形成过程中的力和应力，但不能告诉我们切屑内部的应变，除非使用计算方法。本文描述了微尺度磨削过程中切屑形成的机理，并解释了磨削晶粒的变形对切屑剪切应变速率和平均晶粒尺寸的影响。

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

International Journal of Nanoparticles Engineering-Mechanical Engineering

CiteScore

1.60

自引率

0.00%

发文量