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A Novel Computational Model for Tilting Pad Journal Bearings with Soft Pivot StiffnessesTao, Yujiao 1988- 14 March 2013 (has links)
A novel tilting pad journal bearing model including pivot flexibility as well as temporal fluid inertia effects on the thin film fluid flow aims to accurately predict the bearing forced performance. The predictive model also accounts for the thermal energy transport effects in a TPJB. A Fortran program with an Excel GUI models TPJBs and delivers predictions of the bearing static and dynamic forced performance. The calculation algorithm uses a Newton-Raphson procedure for successful iterations on the equilibrium pad radial and transverse displacements and journal center displacements, even for bearings pads with very soft pivots.
The predictive model accounts for the effect of film temperature on the operating bearing and pad clearances by calculating the thermal expansion of the journal and pad surfaces. The pad inlet thermal mixing coefficient (lambda) influences moderately the predicted fluid film temperature field.
Pad pivot flexibility decreases significantly and dominates the bearing stiffness and damping coefficients when the pivot stiffness is lower than 10% of the fluid film stiffness coefficients (with rigid pivots). Pivot flexibility has a more pronounced effect on reducing the bearing damping coefficients than the stiffness coefficients. Pad pivot flexibility may still affect the bearing behavior at a light load condition for a bearing with a large pad preload.
Pad pivot flexibility, as well as the fluid inertia and the pads’ mass and mass moment of inertia, could influence the bearing impedance coefficients, in particular at high whirl frequencies. The stiffness and damping coefficients of a TPJB increase with a reduction in the operating bearing and pad clearances.
The work delivers a predictive tool benchmarked against a number of experimental results for test bearings available in the recent literature. The static and dynamic forced performance characteristics of actual TPJBs can not be accurately predicted unless their pad flexibility and pivot flexibility, fluid film temperature, pad inlet thermal mixing coefficient, operating bearing and pad clearances, among others are well known in advance. However, the extensive archival literature showcasing test procedures and experimental results for TPJBs does not report the above parameters. Thus, reasonable assumptions on the magnitude of certain elusive parameters for use in the predictive TPJB model are necessary.
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Static characteristics and rotordynamic coefficients of a four-pad tilting-pad journal bearing with ball-in-socket pivots in load-between-pad configurationHarris, Joel Mark 15 May 2009 (has links)
Static characteristics and rotordynamic coefficients were experimentally
determined for a four-pad tilting-pad journal bearing with ball-in-socket pivots in loadbetween-
pad configuration. A frequency-independent [M]-[C]-[K] model fit the
measurements reasonably well, except for the cross-coupled damping coefficients. Test
conditions included speeds from 4,000 to 12,000 rpm and unit loads from 0 to 1896 kPa
(0 to 275 psi).
The test bearing was manufactured by Rotating Machinery Technology (RMT),
Inc. Though it has a nominal diameter of 101.78 mm (4.0070 in.), measurements
indicated significant bearing crush with radial bearing clearances of 99.6 μm (3.92 mils)
and 54.6 μm (2.15 mils) in the axes 45º counterclockwise and 45º clockwise from the
loaded axis, respectively. The pad length is 101.6 mm (4.00 in.), giving L/D = 1.00.
The pad arc angle is 73º, and the pivot offset ratio is 65%. The preloads of the loaded
and unloaded pads are 0.37 and 0.58, respectively.
A bulk-flow Navier-Stokes model was used for predictions, using adiabatic
conditions for the bearing fluid. Because the model assumes constant nominal
clearances at all pads, the average of the measured clearances was used as an estimate.
Eccentricities and attitude angles were markedly under predicted while power loss was
under predicted at low speeds and very well predicted at high speeds. The maximum detected pad temperature was 71ºC (160ºF) and the rise from inlet to maximum bearing
temperature was over predicted by 10-40%.
Multiple-frequency force inputs were used to excite the bearing. Direct stiffness
and damping coefficients were significantly over predicted, but addition of a simple
stiffness-in-series model substantially improved the agreement between theory and
experiment. Direct added masses were zero or negative at low speeds and increased
with speed up to a maximum of about 50 kg; they were normally greater in the unloaded
direction. Although significant cross-coupled stiffness terms were present, they always
had the same sign. The bearing had zero whirl frequency ratio netting unconditional
stability over all test conditions. Static stiffness in the y direction (obtained from steadystate
loading) matched the rotordynamic stiffness Kyy (obtained from multiple-frequency
excitation) reasonably at low loads but poorly at the maximum test load.
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