A Flow Starvation Model for Tilting Pad Journal Bearings and Evaluation of Frequency Response Functions: A Contribution Towards Understanding the Onset of Low Frequency Shaft Motions

Rotating machinery relies on engineered tilting-pad journal bearings (TPJB) to provide static load support with minimal drag power losses, safe pad temperatures, and ensuring a rotordynamic stable rotor operation. End users focus on reducing the supplied oil flow rate into a bearing to both lower operational costs and to increase drive power efficiency. This paper presents measurements of the steady-state and dynamic forced performance of a TPJB whilst focusing on the influence of supplied oil flow rate, below and above a nominal condition (50% and 150%). The test bearing has five pads, slenderness ratio L/D = 0.4, spherical pivots with pad offset = 50% and a preload ∼ 0.40, with a clearance to radius ratio (Cr/R) ≈ 0.001 at room temperature. The bearing is installed under a load-between-pads (LBP) orientation and has a flooded housing with end seals. The test conditions include operation at various shaft surface speeds (32 m/s-85 m/s) and specific static loads from 0.17 MPa to 2.1 MPa. A turbine oil lubricates the bearing with a speed-dependent flow rate delivered at a constant supply temperature. Measurements obtained at a steady thermal equilibrium include the journal static eccentricity and attitude angle, the oil exit temperature rise, and the pads’ subsurface temperatures at various locations, circumferential and axial. The rig includes measurement of the drive torque and shaft speed to produce the bearing drag power loss. Dynamic force coefficients include stiffness, damping, and virtual-mass coefficients. As expected, the drag power and the lubricant temperature rise depend mainly on shaft speed rather than on applied load. A reduction in oil flow rate to 50% of its nominal magnitude causes a modest increase in journal eccentricity, a 15% reduction in drag power loss, a moderate raise (6°C) in pads’ subsurface temperatures, a slight increase (up to 6%) in the direct stiffnesses, and a decrease (up to 7%) in direct damping coefficients. Conversely, a 1.5 times increase in oil flow rate causes a slight increase (up to 9 %) in drag power loss, a moderate reduction of pads’ temperatures (up to 3°C), a maximum 5% reduction in direct stiffnesses, and a maximum 10% increase in direct damping. The paper also presents comparisons of the test results against predictions from a thermo-elasto-hydrodynamic lubrication model. In conclusion, a 50% reduced oil flow rate only causes a slight degradation in the test bearing static and dynamic force performance and does not make the bearing operation unsafe for tests with surface speed up to 74 m/s. As an important corollary, the measured bearing drag power differs from the conventional estimate derived from the product of the supplied flow rate, the lubricant specific heat and the oil exit temperature rise.

show abstract

On the effects of oil film characteristics in the starved bearing on the subsynchronous vibration of turbine rotor

Sugimura

Inoue

Yabui

2022

Transactions of the JSME (In Japanese)

View full text Add to dashboard Cite

Some examples of subsynchronous vibration occurred in the starved bearing condition are reported in the API 684 Standard Paragraph. It is introduced that the subsynchronous vibration was experienced in the high-speed balancing test facility in the vacuum condition and the cause is confirmed to be the starvation of bearing. Because in the vacuum condition of the test facility the pressure inside the bearing housing was low and estimated to be starved. In this example the installation of the proper end seals in the bearing housing can increase the inside pressure of the bearing housing and avoid the subsynchronous vibration. The authors experienced the similar operation in the same situation in the high-speed balancing facility. The rotor type is a back-pressure steam turbine for the turbo generator unit. The bearing types is 5 pad tilting pad bearing. The effects of starved oil film on the subsynchronous vibration was doubted. But generally it is difficult to perform the fluid film analysis in the starved bearing because it requires many complex steps in the analysis. Therefore, the analysis in this paper is performed with applying smaller size bearing pads to simulate the starved bearing film conditions with carrying same bearing load. The size of bearing pads is changed depending on the estimated starved oil film. The effects of the estimated starved film condition on the stability in the rotor and bearing system can be evaluated by applying dynamic analysis to the rotor-bearing system. From the results the excessive small damping ratios in the system could be obtained and the subsynchronous rotor instability was confirmed.

show abstract

A Flow Starvation Model for Tilting Pad Journal Bearings and Evaluation of Frequency Response Functions: A Contribution Towards Understanding the Onset of Low Frequency Shaft Motions

Cited by 3 publications

References 12 publications

Investigation on Axial Displacement Fault Mechanism Based on Dynamic Characteristic Coefficients Identification of Tilting-Pad Thrust Bearing

Investigation on Axial Displacement Fault Mechanism Based on Dynamic Characteristic Coefficients Identification of Tilting-Pad Thrust Bearing

On the Effect of Supplied Flow Rate to the Performance of a Tilting-Pad Journal Bearing: Static Load and Dynamic Force Measurements

On the effects of oil film characteristics in the starved bearing on the subsynchronous vibration of turbine rotor

Contact Info

Product

Resources

About