Dynamic Behaviour of Rotating Machinery
The preceding chapters have been devoted to the study of the dynamic behaviour of structures, i.e., of mechanical systems that are stationary with respect to an inertial frame of reference, apart from the vibratory motion that is the object of the study. Many machine elements, however, do not comply with this definition since, owing to their rotational motion, it is not possible to define an inertial system of reference in which the element is stationary.
KeywordsCritical Speed Journal Bearing Spin Speed Gyroscopic Effect Hydrodynamic Bearing
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- A. Muszynska, Rotor instability, Senior Mechanical Engineering Seminar, Carson City, June, 1984.Google Scholar
- See, for example, F.M. Dimentberg, Flexural vibrations of rotating shafts, Butterworths, London, England, 1961.Google Scholar
- O. Reynolds, On the theory of lubrication and its applications to mr. Towers’ experiments, Phil. Trans. Soc., London, Vol. 177, (1886), 154–234.Google Scholar
- P.C. Warner, Static and dynamic properties of partial journal bearings, J. of Basic Engineering, Trans. ASME, Series D, 85, (1963), 244.Google Scholar
- See, as an example, A. Tondl, Some problems in rotor dynamics, Czechoslovak Academy of Sciences, Prague, Czechoslovakia, 1965; and A. Muszynska, Rotor instability, Senior Mechanical Engineering Seminar, Carson City, June, 1984.Google Scholar
- F. Ehrich, D. Childs, Self-excited vibration in high performance turbomachinery, Mech. Eng., May, (1984).Google Scholar
- As an example, see H. Schneider, Balancing technology, Schenck, Darmstadt, Germany, 1974.Google Scholar