Experimental Response of a Rotor Supported on Rayleigh Step Gas Bearings

Zhu, Xuehua; ́s, Luis San Andre

doi:10.1115/gt2005-68296

Cited by 12 publications

(12 citation statements)

References 34 publications

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“…Tello [12] has theoretically studied the regularity of the solution to the Reynolds equation in Rayleigh step type bearings for both compressible and incompressible fluids by employing a rigorous mathematical approach. Zhu [13] has investigated both numerically and experimentally the response of a rotor supported on Rayleigh step gas bearing using Galerkin finite element method. Thermohydrodynamic lubrication (THL) analysis method has also been applied to the study of (Rayleigh) step bearing by Hideki [14].…”

Section: Introductionmentioning

confidence: 99%

“…In a most recent work, Naduvinamani and Siddangouda [16] have also studied the effect of surface roughness on the hydrodynamic lubrication of porous step-slider bearings with couple stress fluids theoretically. Rayleigh step bearings have been of interest in industry from shaft-bearing systems such as (high-speed) turbomachinery to microelectromechanical systems (MEMS) as well as the computer industry in devices such as magnetic head recording or hard/floppy disc drives [12][13][14]. Their higher load capacity and cheap/easy manufacturing has made them more favourable to be used especially in situations wherever the air or gases are used as a lubricant in which because of their lower viscosity application of a hybrid hydrostatic/hydrodynamic mode is inevitable.…”

Section: Introductionmentioning

confidence: 99%

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Analytical analysis and optimisation of the Rayleigh step slider bearing

Rahmani

Shirvani

2009

Tribology International

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• This is the author's version of a work that was accepted for publication in the journal, Tribology International. Changes resulting from the publishing process, such as peer review, editing, corrections, structural format- AbstractIn tribology, the Rayleigh step is known as a bearing with the highest load capacity amongst all other possible bearing geometries. In classical resources on tribology, it is also shown that there is an optimum geometry for the Rayleigh step providing the highest load capacity. However, the analyses are confined to a special case where the effect of hydrostatic pressure is neglected. Furthermore, the possible optimum parameters in terms of the friction force and/or friction coefficient as well as the lubricant flow rate have not been discussed. In this study, the Rayleigh step is comprehensively analysed including the effect of variations of pressure at the boundaries on the optimum parameters. In addition, the bearing is also optimised considering lubricant flow rate, friction force and friction coefficient. It is shown that the optimum bearing parameters are strictly dependent on the variations of the pressure at the boundaries. It is also verified that the optimum point(s) in terms of load capacity are not necessarily equal to the optimum point(s) considering friction coefficient and/or lubricant flow rate even though if there is no pressure difference between bearing endings.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Analytical analysis and optimisation of the Rayleigh step slider bearing

Rahmani

Shirvani

2009

Tribology International

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“…The most recent and complete work dealing with the experimental analysis of aerostatic bearings are those of San Andres et al [5][6][7][8][9] and of the research team at Politécnico di Torino [10][11][12]. The experimental results of San Andres and co-workers were obtained on a test rig consisting of a light rotor supported by two identical bearings.…”

Section: Introductionmentioning

confidence: 99%

Experimental Analysis of the Dynamic Characteristics of a Hybrid Aerostatic Bearing

Rudloff

Arghir

Bonneau

et al. 2012

Journal of Engineering for Gas Turbines and Power

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The dynamic characteristics of a hybrid aerostatic bearing are experimentally investigated on a test rig consisting of a rigid rotor driven by an impulse turbine. The rotor is horizontally mounted and is supported by two identical aerostatic bearings. Both the impulse turbine and the aerostatic hybrid bearings are fed with air. The feeding pressures in the bearings can be as high as 7 bars and rotation speeds can reach 60 krpm so the dynamic load on the rotor is much larger than the static load engendered by its weight. Excitations are applied either via an impact hammer or via unbalancing masses. The measuring instruments record the bearing feeding pressures, the rotation speed, the impact force, the displacements of the two bearings, and the bearing housing accelerations. The experimental data together with the equations of motion of the rotor enables the identification of the dynamic coefficients of the bearings. A second identification procedure using the same impact hammer is also possible as force transducers are mounted between the bearing housing and its support. The dynamic coefficients of the bearings can then be obtained from the equation of motion of its housing. Unbalance response provide a convenient way for verifying the accuracy of the identified dynamic coefficients. Therefore these coefficients are injected in the equations of motion of a four degrees of freedom rigid rotor and the theoretical results are compared with values measured on the test rig. Comparisons show that predictions are acceptable but become less accurate at high rotation speeds where large dynamic forces are needed for exciting the corresponding synchronous frequencies.

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“…Thus, the solutions of Reynolds lubrication equation for the pressure distribution, load capacity, and frictional coefficient were obtained through a relatively simple calculation and some detailed flow information on Rayleigh step bearing has been neglected [20]. Only a few investigations used the calculation of the Navier-Stokes equations with finite volume method [11] or infinite element method [12,14]. In recent years, the full Navier-Stokes equations have been increasingly applied to solve some lubrication problems [21][22][23].…”

Section: Introductionmentioning

confidence: 99%

“…Zhu [12] investigated both numerically and experimentally the response of a rotor supported on Rayleigh step gas bearing using Galerkin finite element method. Constantinescu et al [13] analyzed the pressure variation due to fluid inertia effects in Rayleigh step bearings.…”

Section: Introductionmentioning

confidence: 99%

Recirculation Flow and Pressure Distributions in a Rayleigh Step Bearing

Shen

Yan

Dai

et al. 2018

Advances in Tribology

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Flow characteristics in the Rayleigh step slider bearing with infinite width have been studied using both analytical and numerical methods. The conservation equations of mass and momentum were solved utilizing a finite volume approach and the whole flow field was simulated. More detailed information about the flow patterns and pressure distributions neglected by the Reynolds lubrication equation has been obtained, such as jumping phenomenon around a Rayleigh step, vortex structure, and shear stress distribution. The pressure distribution of the Rayleigh step bearing with optimum geometry has been numerically simulated and the results obtained agreed with the analytical solution of the classical Reynolds lubrication equation. The simulation results show that the maximum pressure of the flow field is at the step tip not on the lower surface and the increment of the strain rate from Navier-Stokes equation is approximately 49 percent greater than that from Reynolds theory at the step tip. It is also shown that the position of the maximum pressure of the lower surface is a little less than the length of the first region. These results neglected by the Reynolds lubrication equation are important for designing a bearing.

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Experimental Response of a Rotor Supported on Rayleigh Step Gas Bearings

Cited by 12 publications

References 34 publications

Analytical analysis and optimisation of the Rayleigh step slider bearing

Analytical analysis and optimisation of the Rayleigh step slider bearing

Experimental Analysis of the Dynamic Characteristics of a Hybrid Aerostatic Bearing

Recirculation Flow and Pressure Distributions in a Rayleigh Step Bearing

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