Sage Journals: Discover world-class research

Abstract

Prediction of machine dynamics at the design stage is a challenge due to lack of adequate methods for identifying and handling the nonlinearities in the machine joints, which appear as the nonlinear restoring force function of relative displacement and relative velocity across the joint. This paper discusses identification of such a nonlinear restoring force function for an industrial translational guide for use with the Nonlinear Receptance Coupling Approach (NLRCA) to evaluate machine dynamic characteristics. Translational guides are among the most commonly used joints in machine tools. Both parametric and nonparametric techniques have been employed to identify the nonlinearities. A novel parametric model based on Hertzian contact mechanics has been derived for the translational guide. A nonparametric method based on two-dimensional Chebyshev polynomials is also used. The models derived from the two techniques, i.e., parametric and nonparametric, are fitted to the experimental data derived from static and dynamic tests to get the restoring force as a function of relative displacement and relative velocity across the joint. The nonlinear representation obtained from both techniques is later converted into the describing function representation which is needed for evaluation of machine dynamic characteristics using the NLRCA. The describing function representations obtained from the two approaches are compared. The design of experiments for evaluating the nonlinearities in such industrial machine tool joints is a challenge, requiring careful alignment and calibration, because they are typically very stiff. This constrains the dynamic experiments to be carried out at high frequencies (e.g. 2000—7000 Hz) where the experimental readings are very sensitive to errors in geometry and calibration.

Keywords

machine dynamics nonlinear joints receptance coupling frequency response functions.

Get full access to this article

View all access options for this article.

References

Atherton, D.P. , 1975, Nonlinear Control Engineering, Van Nostrand, New York.

Benhafsi, Y. , Penny, J.E.T. , and Friswell, M.I. , 1995, "Identification of Damping Parameters of Vibrating Systems with Cubic Stiffness Nonlinearity" in Proceedings of the 13th International Modal Analysis Conference, Nashville, TN, pp.623- 629.

Bishop, R.E.D. and Johnson, D.C. , 1960, The Mechanics of Vibrations, Cambridge University Press, Cambridge.

Dahl, P.R. , 1976, "Solid friction damping of mechanical vibrations ," AIAA Journal 14(12), 1675.

de Wit, C.C. , Olsson, H. , Astrom, K.J. , and Lischinsky, P. , 1995, "New model for control of systems with friction ," IEEE Transactions on Automatic Control 40(3), 419.

Dhupia, J. , Powalka, B. , Ulsoy, A.G. , and Katz, R. , 2006, "Effect of a nonlinear joint on the dynamic performance of a machine tool," in Proceedings of CIRP - Second International Conference on High Performance Cutting, Vancouver, BC, Canada.

Dhupia, J. , Powalka, B. , Ulsoy, A.G. , and Katz, R. , 2007, "Effect of a nonlinear joint on the dynamic performance of a machine tool," ASME Journal of Manufacturing Science and Engineering 129(5), 943-950.

Fahey, S. O'F. and Nayfeh, A.H. , 1998, "Experimental nonlinear identification of a single structural mode," in Proceedings of the 16th International Modal Analysis Conference, Santa Barbara, CA, February 2-5, pp.737.

Ferreira, J.V. and Ewins, D.J. , 1996, "Nonlinear receptance coupling approach based on describing functions," in Proceedings of 14th International Modal Analysis Conference, Dearborn, MI, pp.1034-1040.

10.

Greenwood, J.A. , and Williamson, J.B.P. , 1966, "Contact of nominally flat surfaces," in Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences 295(1442), pp.1442.

11.

Johnson, K.L. , 1982, "100 years of Hertz contact," in Proceedings of the Institution of Mechanical Engineers, vol. 196, pp.363-378.

12.

Kapania, R.K. , and Park, S. , 1996, "Parametric identification of nonlinear structural dynamic systems using finite elements in time," in Proceedings of the 37th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference and Exhibit, Salt Lake City, UT , April 15-17, pp.674.

13.

Kreyszig, E. , 1999, Advanced Engineering Mathematics, Wiley, New York.

14.

Lee, G.M. , 1997, "Estimation of non-linear system parameters using higher-order frequency response functions," Mechanical Systems and Signal Processing 11(2), 219.

15.

Malatkar, P. , and Nayfeh, A.H. , 2003, "A parametric identification technique for single- degree-of-freedom weakly nonlinear systems with cubic nonlinearities," Journal of Vibration and Control 9(3-4),317.

16.

Masri, S.F. , Sassi, H. , and Caughey, T.K. , 1982a, "Nonparametric identification of nonlinear systems ," in Proceedings of the US National Congress of Applied Mechanics , Ithaca, NY, June 21-25, pp.476.

17.

Masri, S.F. , Sassi, H. , and Caughey, T.K. , 1982b, "Nonparametric identification of nearly arbitrary nonlinear systems," ASME Journal of Applied Mechanics 49(3),619.

18.

Mohammad, K.S. , Worden, K. , and Tomlinson, G.R. , 1992, "Direct parameter estimation for linear and non-linear structures," Journal of Sound and Vibration 152(3),471.

19.

Moon, Y.-M. , 2000, Reconf igurable Machine Tool Design: Theory and Application , University of Michigan, Ann Arbor , USA.

20.

Moon, Y.-M. and Kota, S. , 2002, "Design of reconfigurable machine tools," ASME Journal of Manufacturing Science and Engineering 124(2), 480-483.

21.

Rivin, E.I. , 1999, Stiffness and Damping in Mechanical Design, Marcel Dekker, New York.

22.

Swevers, J. , Al Bender, F. , Ganseman, C.G. , and Prajogo, T. , 2000, "Integrated friction model structure with improved presliding behavior for accurate friction compensation," IEEE Transactions on Automatic Control 45(4), 675.

23.

Worden, K. and Tomlinson, G.R. , 2001, Nonlinearity in Structural Dynamics: Detection, Identif ication, and Modelling, Institute of Physics Publishing , Bristol, U.K.

24.

Yasuda, K. , Kamiya, K. , and Komakine, M. , 1997, "Experimental identification technique of vibrating structures with geometrical nonlinearity," ASME Journal of Applied Mechanics 64(2), 275.

25.

Yasuda, K. and Kamiya, K. , 1999, "Experimental identification technique of nonlinear beams in time domain," Nonlinear Dynamics 18(2), 185.

26.

Yigit, A.S. and Ulsoy, A.G. , 2002, "Dynamic stiffness evaluation for reconfigurable machine tools including weakly non-linear joint characteristics," in Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 216(1), 87-101.

Experimental Identification of the Nonlinear Parameters of an Industrial Translational Guide for Machine Performance Evaluation

Abstract

Keywords

Get full access to this article

References