An investigation of surface roughness in micro-end-milling of metals
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Li, Huaizhong
Wang, Jun
Yuan, Yanjie
Zhang, Dawei
Kwok, Ngaiming
Thai, Nguyen
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Abstract
This paper presents an experimental study of the effects of cutting parameters of micro-end-milling process on the machined surface roughness, in order to find the optimal operation conditions for improved surface finish. Three types of metals, namely 6160 aluminium alloy, brass, and AISI 1040 steel, are used as work materials. The effect of material property on the surface roughness is investigated. It is found that under the same machining condition, the machined surface quality of aluminium alloy is the worst, while that of brass is the best. A multiple regression model for the surface roughness is developed, which includes the effects of cutting speed, feedrate, and the interaction between them. Results based on analysis of variance (ANOVA) show that the cutting speed is the most significant factor on surface roughness. The residual analysis indicates that the multiple regression model is valid and agrees with the experimental results.
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Australian Journal of Mechanical Engineering
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© 2016 Engineers Australia. Published by Taylor & Francis (Routledge). This is an Accepted Manuscript of an article published by Taylor & Francis in Australian Journal of Mechanical Engineering on 26 Jul 2016, available online: http://www.tandfonline.com/doi/full/10.1080/14484846.2016.1211472
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Manufacturing engineering
Maritime engineering
Mechanical engineering
Mechanical engineering not elsewhere classified