Abstract
This paper investigates the effects of machining tool path and cutting layer strategies on machining efficiency and accuracy in micro-milling of linear and circular micro-geometric features. Although micro-milling includes many characteristics of the conventional machining process, detrimental an effect in downscaling the process can be excessive tool wear which could, in turn, increase the machining forces and hence affect the geometrical accuracy and surface roughness. Most of the research in micro milling reported in the literature has focused on optimising machining parameters, such as feed rate and depth of cut to achieve lower cutting forces, better surface roughness, and better machining efficiency. However, is there yet little known about the effect and stability of machining tool paths and cutting layers strategies for the micro-milling process. Various tool path strategy, including lace(0°), lace(45°), lace(90°), concentric and waveform in producing linear and circular micro geometric features were compared and analysed. The effect of various cutting layer strategies in producing thin walled structure was investigated. The optimisation method with respect to surface roughness and dimensional accuracy is proposed for selection of optimum machining strategies experimentally tested. Experimental results show that the most commonly used strategy lace(0°) and concentric, reported in the literature have provided the least satisfactory machining performance, while the waveform strategy provides the best balance of machining performance for both linear and circular geometries. Adopting an optimum sequence of material removal layer in micromachining of thin walls has proven to improve the overall accuracy. This paper concludes that an optimal choice of machining strategies in process planning is as important as balancing machining parameters to achieve desired machining performance.
Highlights
The nature of manufacturing has changed to reflect the advancement on customer demand for high production rate, process efficiency, and product accuracy[1]
Current tool manufacturing restriction leads to micro tool cutting edge radius to be comparable with size of part geometry beside available equipment cannot achieve an optimum machining parameter required for micro tools within feasible cost[5]
Considering different manufacturing goal, in both cases of high accuracy and low surface roughness criterion waveform had scored the highest this trend changed when optimisation goal focused on productivity, Lace 90 identified to be most suitable whereas waveform was the least desired tool path to be used
Summary
The nature of manufacturing has changed to reflect the advancement on customer demand for high production rate, process efficiency, and product accuracy[1]. This paper experimentally investigate the effect of comonly used toolpaths in micromachining of circular and linear geometries and the effect of different cutting layer strategies using constant feedrate by analysing surface roughness, geometric accuracy and machining time. An optimization method is proposed to provide an optimum tool path and cutting layer strategy selection at different machining stages with an aim to improve machining efficiency and accuracy. 2-Methodology of process planning for high-speed milling This work consist of three phases; Modeling, experiment and optimization for optimum selection of toolpath and machining strategy by looking at 4 common manufacturing aims: machining accuracy,machining surface finish, productivity and balance of all three. Follow by machining of on thin wall structures using proposed cutting layer stratgies and machining of linear and circular geometrise using comonly used toolpaths to collect neccecery data on geometrical accuracy, surface roughness and machining time.
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