Open Access
Mechanics & Industry
Volume 16, Number 1, 2015
Article Number 105
Number of page(s) 9
Published online 17 October 2014
  1. S. Yoshimoto, Theory and Operating Principle of Aerostatic Bearings, Design Eng. 37 (2002) 51–56 [Google Scholar]
  2. H. Sugai, S. Nakayama, Air bearing for a dental handpiece, U.S. Patent No. 4209293, 1980 [Google Scholar]
  3. H. Fukuyama, Porous, static pressure air bearing device in a dentist’s handpiece, U.S. Patent No. 3969822, 1976 [Google Scholar]
  4. H. Mizumoto, T. Matsubara, An aerostatically controlled restrictor for obtaining an infinite stiffness aerostatic thrust bearing, J. Japan Soc. Precision Eng. 55 (1989) 135–140 [CrossRef] [Google Scholar]
  5. R. Holmes, J.E.H. Sykes, The Vibration of an Aero-engine Rotor Incorporating Two Squeeze-film Dampers, J. Aerospace Eng. 210 (1996) 39–51 [Google Scholar]
  6. S. Togo, Air bearing design guide plan, Kyoritsu Publishing, 1985 [Google Scholar]
  7. P. Matta, L. Rudloff, M. Arghir, Experimental investigation of air bearings dynamic coefficients, Mechanics & Industry 11 (2010) 477–488 [CrossRef] [EDP Sciences] [Google Scholar]
  8. F.T. Bakers, A Magnetic Journal Bearing, Philips Tech. Rev. 22 (1961) 232–238 [Google Scholar]
  9. N. Groom, J.F. Antaki, Design Formulas for Permanent-Magnet Bearings, Trans. ASME 125 (2003) 734–738 [Google Scholar]
  10. S.Y. Yoo, W.Y. Kim, S.J. Kim, W.R. Lee, Y.C. Bae, M. Noh, Optimal Design of Non-Contact Thrust Bearing Using Permanent Magnet Rings, Int. J. Precision Eng. Manuf. 12 (2011) 1009–1014 [CrossRef] [Google Scholar]
  11. G. Sobotka, R. Lange, Characteristics of a Magnetic Rotor Bearing for Active Vibration Control, Conf. On Vibrations in Rotating Machinery (1976) C239/76 [Google Scholar]
  12. M. Biedinger, D. Lemoine, Shape Sensitivity Analysis of Magnetic Force, IEEE Trans. Magn. 33 (1997) 2309–2316 [CrossRef] [Google Scholar]
  13. G. Jones, Magnetic Bearing Can Improve Reliability and Performance of Pumps, World Pumps 366 (1997) 48–49 [Google Scholar]
  14. S. Morosi, I.F. Santos, Stability Analysis of Flexible Rotors Supported by Hybrid Permanent Magnet-Gas Bearings, 11th Pan-American Congress of Applied Mechanics – PACAM XI, 2010, pp. 1–8 [Google Scholar]
  15. S. Morosi, From Hybrid to Actively-Controlled Gas Lubricated Bearings – Theory and Experiment, Ph.D. Thesis, Department of Mechanical Engineering, Technical University of Denmark, 2011 [Google Scholar]
  16. S.K. Ro, S. Kim, Y. Kwak, C.H. Park, A linear air bearing stage with active magnetic preloads for ultraprecise straight motion, Precision Eng. 34 (2010) 186–194 [CrossRef] [Google Scholar]
  17. Q.C. Tan, W. Li, B. Liu, Investigations on a permanent magnetic-hydrodynamic hybrid journal bearing, Tribology Int. 35 (2002) 443–448 [CrossRef] [Google Scholar]
  18. Y.D. Chen, Design and development of hybrid magnetic-aerostatic bearing and performance investigation, Master thesis of national Taiwan university, 1996 [Google Scholar]
  19. L. Licht, D.D. Fuller, B. Sternlicht, Self-Excited Vibration of an Air Lubricated Thrust Bearing, Trans. ASME 80 (1958) 411–414 [Google Scholar]
  20. C.H.T. Pan, Spectral Analysis of gas bearing system for stability studies, Ninth Midwestern Mechanics Conference, 1965 [Google Scholar]

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