The Dynamic Analysis of Micro-Scale Edge in the Process of Micromilling

Ya Dong Gong; Jin Feng Zhang; Jun Cheng; Xue Long Wen; Chao Wang; Guo Qiang Yin

doi:10.4028/www.scientific.net/AMR.797.628

Paper Titles

Study on the Restraint Method of Thermal Deformation in the Machine Tools
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Experiment Research on Grinding Temperature of Micro-Grinding H62
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Finite Element Simulation of Minimum Uncut Chip Thickness in Micro Mill-Grinding Ti6Al4V Based on Single-Edge Single-Grit Model
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The Dynamic Analysis of Micro-Scale Edge in the Process of Micromilling
p.628

Fabrication of Surface Microtexture by Vibration Assisted Cutting
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Bending of Drill and Radial Forces in Micro Drilling
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An Approach to Improve Machined Surface Finish in Micro Milling
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Experimental Research on Surface Residual Stress of Quenched GCr15 Steel in Ultrasonic Aided Turning
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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 797The Dynamic Analysis of Micro-Scale Edge in the...

The Dynamic Analysis of Micro-Scale Edge in the Process of Micromilling

Abstract:

The micro-processing technology has gradually become a hot topic problem, especially in micro-scale milling chatter prevention with the development of the information age. In allusion to the actual case of micro-milling, the dynamic theoretical research is analyzed in-depth about the Fourier method and the average tooth angle method. Compared to two ways, the former is close to the actual processing requirements. The lobes are obtained use the two ways. Micro milling parameters are selected in the stable area and unstable region. Stable and non-stable curve and surface quality of machined parts are obtained after micro-milling test. The chatter points, non-chatter point and uncertain point are obtained in the high spindle speed, which are consistent with theoretical analysis. In contrast, the distribution of chatter points in the low-speed spindle speed. The reason is that the damping effect is produced in the micro-scale milling process. The research of micro-scale milling chatter, which has a certain significance to improve parts of precision machined parts, reduce the wear and tear of the micro-milling blade and extend micro-tool life.

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Periodical:

Advanced Materials Research (Volume 797)

Pages:

628-637

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.797.628

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Online since:

September 2013

Authors:

Ya Dong Gong, Jin Feng Zhang, Jun Cheng, Xue Long Wen, Chao Wang, Guo Qiang Yin

Keywords:

Axial Cutting Depth, Damping Effect, Lobe Diagram, Micro Chatter, Spindle Speed

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