Using finite element software developed for metal cutting by Third Wave Systems we investigate the forces involved in chatter, a self-sustained oscillation of the cutting tool. The phenomena is decomposed into a vibrating tool cutting a flat surface work piece, and motionless tool cutting a work piece with a wavy surface. While cutting the wavy surface, the shearplane was seen to oscillate in advance of the oscillation of the depth of cut, as were the cutting, thrust, and shear plane forces. The vibrating tool was used to investigate process damping through the interaction of the relief face of the tool and the workpiece. Crushing forces are isolated and compared to the contact length between the tool and workpiece. We found that the wavelength dependence of the forces depended on the relative size of the wavelength to the length of the relief face of the tool. The results indicate that the damping force from crushing will be proportional to the cutting speed for short tools, and inversely proportional for long tools.
[1]
Francis C. Moon,et al.
Dynamics and chaos in manufacturing processes
,
1998
.
[2]
J. D. Smith,et al.
Machine-Tool Dynamics: An Introduction
,
1970
.
[3]
Emily Stone,et al.
Nonlinear models of chatter in drilling processes
,
2002
.
[4]
Keith A. Young,et al.
Analysis of Tool Oscillation and Hole Roundness Error in a Quasi-Static Model of Reaming
,
2001
.
[5]
Sean G. Calvert,et al.
The Effect of Process Damping On Stability and Hole Form in Drilling
,
2001
.
[6]
S. A. Tobias.
Machine-tool vibration
,
1965
.
[7]
Keith A. Young,et al.
Theory of Torsional Chatter in Twist Drills: Model, Stability Analysis and Composition to Test
,
2001
.
[8]
Sean G. Calvert,et al.
Low-Frequency Regenerative Vibration and the Formation of Lobed Holes in Drilling
,
2002
.