Analysis of Tilting Effects and Geometric Non-Uniformities in Micro-Hydrostatic Gas Thrust Bearings

Abstract

The MIT microengine rotors are supported by hydrostatic gas journal and hydrostatic gas thrust bearings. Due to the low length-to-diameter ratio of the devices, the thrust bearings play an important role in providing sufficient tilting stiffness to resist any tilting motion about the spinning axis of the rotor. The performance of the thrust bearings can be influenced by geometric nonuniformities such as thrust bearing clearances and orifice diameters and profiles which arise in the process of microfabrication. To enable stable high speed operation of the micro-devices, it is important to quantify these effects. Furthermore, a thrust bearing analysis tool needs to be developed that is able to explore different thrust bearing arrangements and configurations. In this work, an analytical model is established for analyzing the effects of rotor tilt and geometric non-uniformities in micro-hydrostatic gas thrust bearings for application to microturbomachinery. A previously developed model (Teo and Spakovszky [1]) is generalized and extended for application to thrust bearings with orifices arranged in non-axisymmetric configurations. As a consequence of rotor tilt or geometric non-uniformities, the flow through individual orifices of the thrust bearing becomes non-uniform. The orifice flows are in turn coupled to the hydrostatic pressure field in the thrust bearing pad, and a Green’s function approach is adopted to solve the coupled system. The hydrodynamic thrust bearing forces induced by the pumping action of the rotor rotation are determined by solving the Reynolds equation. The model is able to predict thrust bearing tilting stiffness and variations in the thrust bearing mass flow rates as a function of rotor tilting angle for a variety of orifice arrangements. The model can be applied to analyze the effects of non-uniformities in orifice diameter and the presence of clogged orifices on tilting and the concomitant reduction in tilting stiffness. In addition, the effects of orifice taper are analyzed using an influence-coefficient technique for 1-D compressible flows. Results obtained for various taper ratios are presented and discussed. The model serves as a useful tool for specifying design tolerances during the fabrication of micro-hydrostatic gas thrust bearings and is used in the experiments to estimate the tilting angle of the rotor during operation.