Actually Geometry of Milling Tool Involved in Cutting Process

Zhen Yu Shi; Zhan Qiang Liu; Bing Wang

doi:10.4028/www.scientific.net/MSF.723.394

Paper Titles

Experimental Investigations of Size Effect on Cutting Force, Specific Cutting Energy, and Surface Integrity during Micro Cutting
p.371

An Experimental Study on Micro-Cutting Machining of Pure Tungsten
p.377

Method of Precise Tool Setting for Micro Turning
p.383

Analyses of Size Effect on Surface Roughness in Micro Turning Process
p.389

Actually Geometry of Milling Tool Involved in Cutting Process
p.394

Experimental Study on Cutting Force of High-Speed Micro-Drilling Flexible Printed Circuit Board
p.401

Effect of Grain Size of CVD Diamond Film on Cutting Performance of Diamond Coated Micro Drills
p.407

Design and Dynamic Analysis of Micro Milling Machine
p.412

A New Approach to Five-Axis CNC Flute Grinding of Solid End-Mills
p.421

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Actually Geometry of Milling Tool Involved in Cutting Process

Abstract:

The effect of cutting tool geometry has long been an issue in understanding mechanics of cutting process. Tool geometry has significant influence on chip formation, heat generation, tool wear, surface finish and surface integrity during cutting process. This paper presents the actually geometry of milling tool involved in cutting process based on mathematics analytical methods including matrix translation and rotation. Results show that according to the different helix angle and tool fluted, the geometry of cutting tool involved in cutting is different. For two or three-fluted mirco-milling tools, no mater helix angle is 30 or 45, the actually geometry involved in cutting is sphere. Different cutting tool corresponds to different sphere radius. Experiments were set up to validate the effect of cutting tool geometry on cutting forces. Results show that the smaller of the sphere radius of cutting tool, the lower of the cutting force; the larger of the sphere radius, the higher of the cutting force.