Modeling for optimization of circular flat pad aerostatic bearing with a single central orifice-type restrictor based on CFD simulation

For a circular flat pad aerostatic bearing with a single orifice-type restrictor, flow field in the air film is numerically investigated. The formation process of sonic region and shock waves is studied and formation mechanism of the vortex is revealed. Based on flow analysis, the maximum Mach numbe...

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Bibliographic Details
Published in:Tribology international 2017-05, Vol.109, p.206-216
Main Authors: Yifei, Li, Yihui, Yin, Hong, Yang, Xinen, Liu, Jun, Mo, Hailong, Cui
Format: Article
Language:English
Subjects:
Aerodynamics
Aerostatic bearing
Aerostatic bearings
Aerostatics
Bearings
CFD simulation
Computational fluid dynamics
Computer simulation
Constraint modelling
Design optimization
Dynamic stability
Fluid dynamics
Mach number
Mathematical models
Optimization
Orifice-type restrictor
Orifices
Shock waves
Stiffness
Studies
Unsteady flow
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Summary:For a circular flat pad aerostatic bearing with a single orifice-type restrictor, flow field in the air film is numerically investigated. The formation process of sonic region and shock waves is studied and formation mechanism of the vortex is revealed. Based on flow analysis, the maximum Mach number is taken as the benchmark of bearing dynamic stability and used as a constraint in the optimization modeling, for which the rationality is verified through transient flow calculations. The mathematical model for optimization considering both stiffness and dynamic stability is established, and several cases of optimization are performed under different given loads. The results are compared and benefits of the design optimization are demonstrated. •Transonic flow fields in the air film of the aerostatic bearing are analyzed.•The micro-vibration formation mechanism for the bearing system is illustrated.•Formation processes of the shock wave and vortex flow are illustrated.•Bearing optimization is conducted by considering static and dynamic performances.
ISSN:0301-679X
1879-2464
DOI:10.1016/j.triboint.2016.12.044