The dynamic performance of shoe centreless grinding is presented in this paper. A model with a single-mass system was developed and used to evaluate the system response in the time and the frequency domains. Based on the model, stability and critical parameters of the grinding process were studied. Numerical simulations were conducted in MATLAB. The model was verified by experiments from real grinding trials.
SnoeysR.BrownD.Dominating parameters in grinding wheel—and workpiace regenerative charter. In Proceedings of the 10th International Conference on Advances in Machine Tool Design and Research, 1982, pp. 325–347.
2.
NietoF. J.ExtxabeJ. M.GimenezJ. G.Influence of contact loss between workpiece and grinding wheel on the roundness errors in centerless grinding. Int. J. Mach. Tools Mf., 1998, 38, 1371–1398.
3.
ZhangB.WangJ. X.YangF. L.ZhuZ. Q.The effect of machine stiffness on grinding of silicon nitride. Int. J. Mach. Tools Mf., 1999, 39, 1263–1283.
4.
RamosJ. C.VinolasJ.NietoF. J.A simplified methodology to determine the cutting stiffness and the contact stiffness in the plunge grinding process. Int. J. Mach. Tools Mf., 2001, 41, 33–49.
5.
RoweW. B.BarashM. M.Computer method for investigating the inherent accuracy of centerless grinding. Int. J. Mach. Tools Des. Res., 1964, 4, 91–116.
6.
RoweW. B.BarashM. M.KoeningsbergerF.Some roundness characteristics of centerless grinding. Int. J. Mach. Tools Des. Res., 1965, 5, 203–215.
7.
RoweW. B.KoenigsbergerF.The work regenerative effect in centerless grinding. Int. J. Mach. Tools Des. Res., 1965, 4, 175–187.
8.
RoweW. B.RichardsD. L.Geometric stability charts for the centerless grinding process. J. Mech. Engng Sci., 1972, 14(2), 155–158.
9.
RoweW. B.BellW. F.BroughD.Limit charts for high removal rate centerless grinding. Int. J. Mach. Tools Mf., 1987, 27, 15–25.
10.
HahnR. S.LindsaryR. P.Principles of grinding. Part 1: Basic relationships in precision grinding. In Grinding Theory Techniques and Troubleshooting, 1982, pp. 1–10 (Society of Manufacturing Engineers, Dearborn, Michigan).
11.
KingR. I.HahnR. S.Handbook of Modern Grinding Technology, 1986 (Chapman and Hall, London).
12.
ChenX.AllansonD.ThomasA.MoruzziL.RoweW. B.Simulation of feed cycles for grinding between centers. Int. J. Mach. Tools Mf., 1994, 34(5), 603–616.
13.
ChenX.RoweW. B.AllansonD. R.MillsB.A grinding power model for selection of dressing and grinding conditions. Trans. ASME, J. Mfg Sci. Engng, November 1999, 121, 632–637.
14.
YangY.Design of a vacuum-hydrostatic shoe for center-less grinding. PhD dissertation, University of Connecticut, 1998.
15.
BoothroydG.KnightW. A.Fundamentals of Machining and Machine Tools, 1989 (Marcel Dekker, New York).
16.
LiehJ.Semiactive damping control of vibrations in automobiles. J. Vibr. Acoust., 1993, 115, 340–343.
17.
ZhangH.LiehJ.YenD.SongX. Z.RuiX. J.Geometry analysis and simulation in shoe centerless grinding. Trans. ASME, J. Mfg Sci. Engng, 2003, 125, 304–309.
