Simultaneous cutting and grinding of micropins using cylindrical microtools

IF 3.5 2区 工程技术 Q2 ENGINEERING, MANUFACTURING
Kai Egashira, Hinata Okano, Atsuya Fukuyama
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Abstract

Decreasing cutting force is always crucial in cutting processes. One method to achieve this is by minimizing tool wear, for which rotary cutting is a highly effective technique. The use of a cylindrical tool offers the additional benefit of easy tool fabrication, which is especially advantageous for a microtool capable of machining micropins. However, there have been no reported studies on rotary cutting using a cylindrical microtool. It should be noted that if a microtool is fabricated by electrical discharge machining, it is expected to engage in cylindrical grinding as well. This suggests that both rotary cutting and cylindrical grinding can be carried out simultaneously; however, there have also been no reported studies on simultaneous cutting and grinding. Therefore, the present study investigated whether this machining method can perform micropin machining, if it actually involves both cutting and grinding actions, and whether the combination of these actions enhances material removal capability. In turning and grinding experiments, where only one of the tool and workpiece was rotated, both actions were observed. Furthermore, it was confirmed that micropin machining can be performed by rotating both the tool and workpiece, resulting in a decrease in machining force to approximately one-quarter to one-half compared to that of turning. This indicates that simultaneous cutting and grinding was carried out, and the overlap of their actions enhanced material removal capability. In addition, the relationship between the machining conditions and machining force was investigated. At a small depth of cut, a tool with smaller surface roughness exhibited lower machining force than a tool with larger roughness, and the opposite was true at a large depth of cut. Finally, an ultrasmall-diameter micropin with a diameter less than 3 μm was successfully machined using conditions capable of reducing machining force.
使用圆柱形微型工具同时切割和磨削微针
在切割过程中,降低切割力始终是至关重要的。实现这一目标的方法之一是尽量减少刀具磨损,而旋转切削是一种非常有效的技术。使用圆柱形刀具的另一个好处是刀具易于制造,这对于能够加工微型树脂的微型刀具来说尤其有利。不过,目前还没有关于使用圆柱形微型刀具进行旋转切割的研究报告。值得注意的是,如果微工具是通过放电加工制造的,那么预计它也会进行圆柱磨削。这表明旋转切削和圆柱磨削可以同时进行,但目前还没有关于同时切削和磨削的研究报告。因此,本研究调查了这种加工方法是否能进行微细晶加工,是否实际涉及切削和磨削两个动作,以及这两个动作的结合是否能提高材料去除能力。在车削和磨削实验中,只旋转刀具和工件中的一个,就能观察到这两种动作。此外,实验还证实,通过同时旋转工具和工件,可以进行微晶加工,与车削相比,加工力降低了约四分之一到二分之一。这表明,切削和磨削是同时进行的,两者作用的重叠提高了材料去除能力。此外,还研究了加工条件与加工力之间的关系。在切削深度较小时,表面粗糙度较小的刀具比表面粗糙度较大的刀具表现出更低的加工力,而在切削深度较大时则相反。最后,在能够降低加工力的条件下,成功加工出了直径小于 3 μm 的超小直径微针。
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
CiteScore
7.40
自引率
5.60%
发文量
177
审稿时长
46 days
期刊介绍: Precision Engineering - Journal of the International Societies for Precision Engineering and Nanotechnology is devoted to the multidisciplinary study and practice of high accuracy engineering, metrology, and manufacturing. The journal takes an integrated approach to all subjects related to research, design, manufacture, performance validation, and application of high precision machines, instruments, and components, including fundamental and applied research and development in manufacturing processes, fabrication technology, and advanced measurement science. The scope includes precision-engineered systems and supporting metrology over the full range of length scales, from atom-based nanotechnology and advanced lithographic technology to large-scale systems, including optical and radio telescopes and macrometrology.
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