Affiliations: Rotating Machinery and Controls (ROMAC) Lab,
Mechanical and Aerospace Engineering, University of Virginia, Charlottesville,
VA 22901, USA
Abstract: Fluid film journal bearings (FFBs) are used to support high-speed
rotors in turbomachinery which often operate above the rotor first bending
critical speed. The FFBs provide both lateral support and dynamic coefficients:
stiffness, damping, and mass terms, related to machine vibrations. Detailed
numerical values of the bearing dynamic characteristics are necessary for
proper design and operation of rotating machinery. The methods of the identification of fluid film journal bearing
static and dynamic characteristics, particularly the bearing stiffness,
damping, and mass coefficients, from measured data, obtained from different
measurement systems, is reviewed. Many bearing tests have been performed to
validate a number of different theoretical models, including the classical
Reynolds isoviscous model. More advanced bearing models include the
thermohydrodynamic (THD), and thermoelastohydrodynamic (TEHD) approaches. The
advanced models also include turbulence effects which are important as rotor
speeds continue to increase. The range of measured bearing data no longer
includes current operational conditions. The various approaches to the bearing identification problem are
discussed, including the different force excitation methods of incremental
loading, sinusoidal, pseudorandom, impulse, known/additional unbalance, and
non-contact excitation. Also bearing excitation and rotor excitation approaches
are discussed. Data processing methods in the time and frequency domains are
presented. Methods of evaluating the effects of measurement uncertainty on
overall bearing coefficient confidence levels are reviewed. In this review, the relative strengths and weaknesses of bearing
identification methods are presented, and developments and trends in improving
bearing measurements are documented. Future trends in journal bearing
identification improvement are discussed.
Keywords: Fluid film bearing identification, stiffness, damping, inertia, uncertainty
