Forced Vibration and Chatter in Horizontal Milling: An Investigation Using a Structural Model

Abstract

This paper describes an investigation into the characteristics of, and interaction between, forced vibration and chatter in horizontal milling. The machine tool structure was simulated by a single-degree-of-freedom structural model.

The results show that forced vibration amplitudes: (1) vary with cutter speed in a series of resonance peaks; (2) are similar for plain and climb milling, but vary with orientation between the machining direction and the axis of vibration in a different way for the two processes; (3) increase approximately linearly with feed, except at low feeds; (4) pass through maxima and minima as depth of cut is increased.

The amplitudes and frequencies of chatter are distinct from, and depend on machining conditions differently from, those of forced vibration. Peak chatter amplitudes exceed those of forced vibration, but the latter can, under certain machining conditions, exceed chatter amplitudes. Forced vibration can thus be as much of a limitation as chatter when a good surface finish is required.

It was found that the discontinuous cutting of milling suppresses the onset of chatter relative to that for continuous cutting, for otherwise identical machining conditions. This is the reverse of previous contention.

Get full access to this article

View all access options for this article.

References

Koenigsberger

F. K.

Said

S. M.

‘Dynamic performance of a milling machine’, Production Engineer 1960 34, 270.

Andrew

‘Chatter in horizontal milling’, Proc. Instn mech. Engrs 1964–65 179 (Pt 1, No. 28), 877.

Andrew

Tobias

S. A.

‘Vibration in horizontal milling’, Inst. J. Mach. Tool Des. Res. 1962 2, 369.

Koenigsberger

F. K.

Sabberwal

A. J. P.

‘Investigation into the cutting force pulsations during milling operations’, Inst. J. Mach. Tool Des. Res. 1961 1, 15.

Wallace

P. W.

Andrew

‘Machining forces: Some effects of tool vibration’, Jl mech. Engng Sci. 1965 7 (No. 2), 152.

Zorev

N. N.

Communication to reference (2).

Opitz

Dregger

E. V.

Roese

‘Improvement of the dynamic stability of the milling process by irregular tooth pitch’, Proc. 7th M. T. D. R. Conf. 1966, 213.

Tobias

S. A.

Fishwick

‘Theory of regenerative machine tool chatter’, Engineer, Lond. 1958 205, 199.

Broadbent

E. G.

The elementary theory of aeroelasticity (Aircraft Engineering Monograph) 1956, 54 (Bunhill Publ., London).

10.

Sechler

E. E.

Dunn

L. G.

Airplane structural analysis and design 1963 (Dover Publ., New York).

11.

Aizerman

M. A.

Theory of automatic control 1963, Chapter 3 (Pergamon Press, London).

12.

Hannam

R. G.

‘Chatter in gear hobbing’, Ph. D. dissertation, University of Bristol, 1968 (September).

13.

Knight

W. A.

‘Application of the universal machinability chart to the prediction of machine tool stability’. Int. J. Mach. Tool Des. Res. 1968 8, 1.

14.

Knight

W. A.

Sadek

M. M.

‘Dynamic performance and stability of a lathe’ (to be published).

15.

Péters

Vanherck

‘Machine tool stability test and the incremental stiffness’, C. I. R. P., Nottingham, 1968.

16.

Hals

‘Provisional report on co-operative work on the dynamic cutting coefficient carried out at Eindhoven’, Technische Hogeschool, Eindhoven, 1969 (May);C. I. R. P., 1969.

17.

Porter

‘Chatter analysis by the method of D-partition’, Jl mech. Engng Sci. 1965 7 (No. 3), 348.

18.

Porter

‘D-partition analysis of a two-degree-of-freedom system with delayed restoring force’, Jl mech. Engng Sci. 1967 9 (No. 3), 190.

19.

Tlusty

Polacek

‘Beispiele der Behandlung der selbsterregten Schwingungen der Werkzeugmaschinen’, Proc. Third Forschungs und Konstructions Colloquium Werkzeugmaschinen und Betriebswissenschaft, Munich 1957, 131 (Vogel Verlag, Wurzburg).

20.

Tobias

S. A.

Fishwick

‘The vibrations of radial-drilling machines under test and working conditions’, Proc. Instn mech. Engrs 1956 170, 232.

21.

Gurney

J. P.

Tobias

S. A.

‘A graphical analysis of regenerative machine tool instability’, J. Engng Ind., Trans. Am. Soc. mech. Engrs 1962 84 (Series B), 103.

22.

Tobias

S. A.

Sweeney

‘An algebraic method for the determination of the dynamic stability of machine tools’, Proc. Int. Res. in Production Engineering 1963, 475 (Am. Soc. Mech. Engrs, New York).

23.

Merritt

H. E.

‘Theory of self-excited machine tool chatter’, Am. Soc. Mech. Engrs Paper No. 64-WA/Prod-13.

24.

Lemon

J. R.

Ackermann

P. C.

‘Application of self-excited machine tool chatter theory’, J. Engng Ind., Trans. Am. Soc. mech. Engrs 1965 87 (Series B), 471.

25.

Johnson

B. M.

Andrew

‘Chatter when machining aluminium alloy: An investigation using a structural model’, Proc. Instn mech. Engrs 1968–69 183 (Pt 1), 17.

26.

Wallace

P. W.

Andrew

‘Machining forces: Some effects of removing a wavy surface’, Jl mech. Engng Sci. 1966 8 (No. 2), 129.