Schmitz, T.
, Ziegert, J.
, Burns, T.
, Dutterer, B.
and Winfough, W.
(2004),
Tool Length-Dependent Stability Surfaces, Machining Science and Technology, [online], https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=50703
(Accessed April 25, 2024)
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Tool Length-Dependent Stability Surfaces
Published
Author(s)
T L. Schmitz, J C. Ziegert, , , W R. Winfough
Abstract
This paper describes the development of three-dimensional stability surfaces, or maps, that combine the traditional dependence of allowable (chatter-free) chip width on spindle speed with the inherent dependence on tool overhang length, due to the corresponding changes in the system dynamics with overhang. The tool point frequency response, which is required as input to existing stability lobe calculations, is determined analytically using Receptance Coupling Substructure Analysis (RCSA). In this method, a model of the tool, which includes overhang length as a variable, is coupled to an expreimental measurement of the holder/spindle substructure tharough empirical connection parameters. The assembly frequency response at the tool point can then be predicted for variations in tool overhang length. Using the graphs developed in this study, the technique of tool tuning, described previously in the literature, can then be carried out to select a tool overhang length for maximized material removal rate. Experimental results for both frequency response predictions and milling stability are presented.Citation
Machining Science and Technology
Volume
8
Issue
3
Pub Type
Journals
Download Paper
Keywords
dynamics, machine-tool chatter, milling, vibration control
Citation
Created April 19, 2004, Updated October 12, 2021