The dynamic behavior of deep-hole vibratory drilling is analyzed. The mathematical model presented allows the determination of axial tool and workpiece displacements and cutting forces for significant dynamic system behavior such as the engagement and disengagement of the cutting tool into the workpiece material and tool breakthrough. Model parameters include the actual rigidity of the tool and workpiece holders, time-varying chip thickness, time lag for chip formation due to tool rotation and possible disengagement of drill cutting edges from the workpiece due to tool and/or workpiece axial vibrations. The main features of this model are its nonlinearity and inclusion of time lag differential equations, which require numeric solutions. The specific cutting conditions (feed, tool rotational velocity, amplitude and frequency of forced vibrations) necessary to obtain discontinuous chips and reliable removal are determined. Calculated bifurcation diagrams make it possible to derive the relevant domain of user-specified system parameters along with the determination of optimal cutting conditions.

1.
Armarego, E. J. A., and Brown, R. H., 1977, The Machining of Metals, Mashinostroenie, Moscow, p. 325.
2.
Gouskov, A. M., Svetlitsky, V. A., and Voronov, S. A., 1979, “Lateral Auto Vibration Excitation of Deep Hole Drill,” Collection of Papers Raschety na Prochnost, Mashinostroenie, Moscow, No. 20, pp. 172–182.
3.
Hanna
,
N. H.
, and
Tobias
,
S. A.
,
1974
, “
A Theory of Nonlinear Regenerative Chatter
,”
ASME J. Ind.
,
96
,
247
255
.
4.
Marui
,
E.
,
Hashimoto
,
M.
, and
Kato
,
S.
,
1995
, “
Regenerative Chatter Vibration Occurring in Turning with Different Side Cutting Edge Angles
,”
ASME J. Ind.
,
117
, pp.
551
558
.
5.
Stepan, G., and Kalmar-Nagy, T., 1997, “Nonlinear Regenerative Machine Tool Vibrations,” Proceedings of the 1997 ASME Design Engineering Technical Conference, 16th Biennial Conference on Mechanical Vibration and Noise, ASME, Sacramento, DETC/VIB-4021, pp. 1–11.
6.
Poduraev, V. N., 1970, Cutting with Vibrations, Mashinostroenie, Moscow, p. 351.
7.
Kumabe, D., 1985, Vibratory Cutting, Mashinostroenie, Moscow, p. 424.
8.
Poduraev, V. N., and Kibalchenko, A. V., 1993, The Technology of Defense Industry for Manufacturing of Customer Goods, Moscow, Rosconversia, p. 528.
9.
Bayley, P. V., Metzler, S. A., Schaut, A. J., and Young, K. A., 2000, “Theory of Torsional Chatter in Twist Drills: Model, Stability Analysis and Comparison to Test,” Proceedings of the ASME, MED, Vol. 11, pp. 899–908.
10.
Gouskov, A. M., Voronov, S. A., and Nikitin, A. S., 1992, “Stochastic Regimes in Technologic Cutting Processes,” Proceedings of the 2nd International Scientific Technical Conference, Actual Problems of Fundamental Science, Technosphera Inform, Bauman Moscow State Technical University Press, Moscow, Vol. 2, pp. B2–B5.
11.
Stephenson, D. A., and Agapiou, J. S., 1997, Metal Cutting Theory and Practice, Marcel Decker, New York.
12.
Norkin, S. B., 1965, Second Order Differential Equations with Lag Argument, Nauka, Moscow, p. 355.
13.
Hale, J., 1984, Theory of Functional Differential Equations, Mir, Moscow, p. 421.
14.
Kalmar-Nagy, T., and Pratt, J. R., 1999, “Experimental and Analytical Investigation of the Subcritical Instability in Metal Cutting,” Proceedings of the 1999 Design Engineering Technical Conference. 17th ASME Biennial Conference on Mechanical Vibration and Noise, Las Vegas, DETC/VIB-8060, pp. 1–9.
You do not currently have access to this content.