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http://dx.doi.org/10.5050/KSNVN.2008.18.1.110

Amplitude-dependent Complex Stiffness Modeling of Dual-chamber Pneumatic Spring for Pneumatic Vibration Isolation Table  

Lee, Jeung-Hoon (한국과학기술원 기계공학과)
Kim, Kwang-Joon (한국과학기술원 기계공학과)
Publication Information
Transactions of the Korean Society for Noise and Vibration Engineering / v.18, no.1, 2008 , pp. 110-122 More about this Journal
Abstract
Pneumatic vibration isolator typically consisting of dual-chamber pneumatic springs and a rigid table are widely employed for proper operation of precision instruments such as optical devices or nano-scale equipments owing to their low stiffness- and high damping-characteristics. As environmental vibration regulations for precision instruments become more stringent, it is required to improve further the isolation performance. In order to facilitate their design optimization or active control, a more accurate mathematical model or complex stiffness is needed. Experimental results we obtained rigorously for a dual-chamber pneumatic spring exhibit significantly amplitude dependent behavior, which cannot be described by linear models in earlier researches. In this paper, an improvement for the complex stiffness model is presented by taking two major considerations. One is to consider the amplitude dependent complex stiffness of diaphragm necessarily employed for prevention of air leakage. The other is to employ a nonlinear model for the air flow in capillary tube connecting the two pneumatic chambers. The proposed amplitude-dependent complex stiffness model which reflects dependency on both frequency and excitation amplitude is shown to be very valid by comparison with the experimental measurements. Such an accurate nonlinear model for the dual-chamber pneumatic springs would contribute to more effective design or control of vibration isolation systems.
Keywords
Dual-chamber Pneumatic Spring; Complex Stiffness;
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Times Cited By KSCI : 1  (Citation Analysis)
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1 White, F. M., 2003, 'Fluid Mechanics 5th Edition', NewYork : McGraw-Hill
2 Munson, B. R., Young, D. F. and Okiishi, T. H., 1998, 'Fundamentals of Fluid Mechanics 3rd Edition', New York : John Wiley & Sons, Inc
3 Moran, M. J. and Shapiro, H. N., 2004, 'Fundamentals of Engineering Therm Odyamics 5th Edition', New York : John Wiley & Sons
4 Shearer, J. L., 1960, Fluid Power Control : Chap.16 Pneumatic Drives. MIT press
5 Erin, C., Wilson, B. and Zapfe, J., 1998, 'An Improved Model of a Pneumatic Vibration isolator : Theory and Experiment', Journal of Sound and Vibration. Vol. 218, No. 1, pp. 81-101   DOI   ScienceOn
6 Nashif, A. D., Jones, D. I. G., and Henderson, J. P., 1986, 'Vibration Damping', New York : John Wiley & Sons, Inc
7 Lee, J. H. and Kim, K. J., 2006, 'Computation of Complex Stiffness of Inflated Diaphragm in Pneumatic Springs by Using FE Codes', Transactions of the Korean Society for Noise and Vibration Engineering, Vol. 16, No. 9, pp. 919-925   과학기술학회마을   DOI   ScienceOn
8 Oosthuizen, P. H. and Carscallen, W. E., 1997, 'Compressible Fluid Flow', New York : McGraw- Hill
9 Gordon, C. G., 1991, 'Generic Criteria for Vibration-sensitive Equipment', Proceedings of SPIE, SanJose, CA
10 Amick, H., Gendreau, M. and Gordon, C. G., 2002, 'Facility Vibration Issues for Nanotechnology Research', Proceedings of the Symposium on Nano Device Technology, Hsinchu,Taiwan
11 Harris, C. M. and Crede, C. E., 1961, 'Shock and Vibration Handbook', McGraw-Hill
12 DeBra, D. B., 1984, 'Design of Laminar Flow Restrictors for Damping Pneumatic Vibration isolators', CIRP Annals, Vol. 33, No. 1 , pp. 351-356   DOI   ScienceOn