微尺度铣削加工实验研究（英文）

Experimental study on micromilling process parameters

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摘要影响微尺度铣削加工质量的因素中,工艺参数相对于其他动态变化的因素是可控的。针对微尺度铣削工程材料黄铜H68,基于所开发的微尺度铣削机床,应用Taguchi方法,通过实验的方法,以表面粗糙度作为加工质量评价指标,对工艺参数展开了研究。通过对实验结果的极差分析与方差分析,确定了3个关键工艺参数轴向切深、径向切深和每齿进给量对表面粗糙度的影响趋势。结果表明:径向切深对于微尺度铣削黄铜H68影响最大,其次是每齿进给量与轴向切深。本研究对于微尺度铣削类似的延展性材料提供了方法与工艺参考。 Process parameters in microcutting are controllable comparing to other dynamically varied factors affecting the micromachining processes. Based on the Taguchi method,the three key process parameters of the axial depth of cut,the radial depth of cut,and the feed in micromilling of very important engineering material brass H68 are experimentally studied in an orthogonal way on a micromilling machine tool with sub-micron accuracy.The achieved surface roughness in micromilling experiments are used as the evaluation criterion. The extreme difference analysis and the variance analysis of the experimental results have identified the affecting tendencies of the three key process parameters on the final micromilling results. It turns out that the radial depth of cut affects the finished surface roughness most greatly in micromilling of brass H68. The feed and the radial depth of cut have significance on the surface roughness.

作者赵硕学曲庆文刘原勇程祥

机构地区山东理工大学机械工程学院

出处《机床与液压》北大核心 2016年第18期68-72,共5页 Machine Tool & Hydraulics

基金 financially supported by the Natural Science Foundation of Shandong Province, China (ZR2015EL023)

关键词微尺度铣削工艺参数表面粗糙度亚微米精度 Micromilling Process parameters Surface roughness Sub-micron accuracy

分类号 TH164 [机械工程—机械制造及自动化]

作者简介 Corresponding author： Qing-wen QU, Professor. E-mail ： quqingwen@ sdut. edu. cn

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微尺度铣削加工实验研究（英文）

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