An Approach to Improve Machined Surface Finish in Micro Milling

Yunn Shiuan Liao; Chun Lin  Huang

doi:10.4028/www.scientific.net/AMR.797.649

Paper Titles

Finite Element Simulation of Minimum Uncut Chip Thickness in Micro Mill-Grinding Ti6Al4V Based on Single-Edge Single-Grit Model
p.622

The Dynamic Analysis of Micro-Scale Edge in the Process of Micromilling
p.628

Fabrication of Surface Microtexture by Vibration Assisted Cutting
p.638

Bending of Drill and Radial Forces in Micro Drilling
p.642

An Approach to Improve Machined Surface Finish in Micro Milling
p.649

Experimental Research on Surface Residual Stress of Quenched GCr15 Steel in Ultrasonic Aided Turning
p.657

Effect of Low-Frequency Pulsed Magnetic Treatment on Micro-Hardness of High Speed Steel
p.663

Indentation Crack Initiation and Ductile to Brittle Transition Behavior of Fused Silica
p.667

Research on Subsurface Damage Layer Detection during Substrate Processing
p.673

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 797An Approach to Improve Machined Surface Finish in...

An Approach to Improve Machined Surface Finish in Micro Milling

Abstract:

Micro milling has been known to behave quite differently from conventional macro milling. The effect of cutting speed on the machined surface roughness in micro milling of ductile materials was investigated in this paper. The micro flat end milling cutters of the diameters of 0.5 mm and 0.3 mm were taken to machine 6061 aluminum alloy and S20C low carbon steel. For comparison purpose, the cutter of the diameter of 10 mm was tested as well. It is found that the machined surface finish is closely related to the cutting speed. For a large size cutter, the roughness decreases with the increase of cutting speed as expected. But the decreasing trend is valid only up to a certain speed for the small diameter cutters. It is also noted that beyond this speed limit broken and powder type chips form easily. These chips will adhere to the machined surface and tool face and deteriorate machined surface as a result. Based on this finding, an approach by directing the cutting fluid to the cutting zone via high pressure air assistance is proposed. It is verified that the cutting force and its variation are greatly reduced, tool wear becomes less, and finish of the machined surface is significantly improved.