Rotor-bearing systems supported on squeeze film dampers (SFDs) show large amplitude vibratory motions when traversing critical speeds. At these operating conditions air is drawn into the damper thin film clearance generating a bubbly mixture with the lubricant and producing SFD forces not readily predictable with currently available analysis. A continuum model is proposed for describing the motion of a bubbly fluid in an open ended SFD operating with circular centered journal orbits. Computed predictions for peak-peak dynamic pressures and fluid film forces agree reasonably well with experimental measurements conducted on a SFD test rig operating with a controlled air in oil mixture. The bubbly flow model provides an initial procedure towards the reliable design of SFDs in actual operating conditions. [S0742-4787(00)02601-1]

Issue Section:
Technical Papers
Keywords:
lubrication, bubbles, rotors, machine bearings, film flow, damping, vibrations, air
Topics:
Dampers, Lubricants, Pressure, Fluids, Bearings, Clearances (Engineering), Rotors, Bubbles, Fluid films, Bubbly flow
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Copyright © 2000
 by ASME
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