Davies, M.
, Pratt, J.
, Dutterer, B.
and Burns, T.
(2001),
Regenerative Stablity Analysis of Highly Interrupted Machining, Proceedings of the 3rd International Conference on Metal cutting & High Speed Machining, Metz, FR
(Accessed April 17, 2024)
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Regenerative Stablity Analysis of Highly Interrupted Machining
Published
Author(s)
, , ,
Abstract
We discuss theoretical and experimental work that supports the use of very low radia immersion in the high-speed milling of difficult-to-machine materials, such as titanium alloys. Our theory is based upon modeling the cutting process by a kicked harmonic oscillator with delay. Traditional regenerative chatter theory predicts that, for a single degree of freedom system, the most stable speeds are at integral multiples of the natural frequency of the system. The new theory predicts a set of stable speeds at fractions of the damped natural frequency. For small damping, a subset of these stable speeds is approximately the same as predicted by the traditional theory. From a practical point of view, the most important prediction of our new theory is that the number of optimally stable speeds doubles as the ratio p of time per revolution of tool contact with the material to the spindle period becomes small, i.e., pProceedings Title
Proceedings of the 3rd International Conference on Metal cutting & High Speed Machining
Volume
1
Conference Dates
June 27-29, 2001
Conference Location
Metz, FR
Conference Title
3rd International Conference on Metal cutting & High Speed Machining
Pub Type
Conferences
Keywords
high speed machining, interrupted cutting, stability lobes, tool chatter
Citation
Created January 1, 2001, Updated February 19, 2017