Passive shape shifting: A compliant design approach for full film bearings

Abstract

In tribotronic bearing design active components are used to adapt bearing performance to operating conditions. The principle of self-adaptive bearings has also been presented in literature in which a passive modification of geometry was used for a variation in conditions. This work presents an alternative design approach for self-adaptive bearings. This approach is focused on the shift between two known bearing geometries, where each of them is the preferred solution in a part of the operating regime. Using compliant elements in the bearing design allows for passive shape shifting. Four examples are presented which present this behavior for variable velocity and load conditions. The design approach could possibly provide a cheaper alternative for simple active bearing designs, or could be combined with active components in a tribotronics design to improve existing performance.

Keywords

Shape shifting tribotronics full film bearings compliant mechanisms self-adaptive mechanism design

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References

Liu

Wang

Cai

, et al. A review of hydrostatic bearing system: researches and applications. Adv Mech Eng 2017; 9: 168781401773053–27.

Lampaert

Quinci

van Ostayen

RA.

Rheological texture in a journal bearing with magnetorheological fluids. J Magnet Magnet Mater 2020; 499: 166218.

Fesanghary

Khonsari

MM.

On the optimum groove shapes for load-carrying capacity enhancement in parallel flat surface bearings: theory and experiment. Tribol Int 2013; 67: 254–262.

Rohde

SM.

The optimum slider bearing in terms of friction. J Tribol 1972; 94: 275–279.

Liang

Yan

Ouyang

, et al. Thermo-elasto-hydrodynamic analysis and optimization of rubber-supported water-lubricated thrust bearings with polymer coated pads. Tribol Int 2019; 138: 365–379.

de Kraker

van Ostayen

Rixen

DJ.

Calculation of stribeck curves for (water) lubricated journal bearings. Tribol Int 2007; 40: 459–469.

Khonsari

MM.

On the lift-off speed in journal bearings. Tribol Lett 2005; 20: 299–305.

Heinrichson

Santos

IF.

Reducing friction in tilting-pad bearings by the use of enclosed recesses. J Tribol 2008; 130: 1–9.

van Ostayen

RAJ

van Beek

de Kraker

Lift-off of the hydrostatic thrust bearing with elastic surfaces. In: 2004 AIMETA International Tribology COnference, Rome, Italy, 14–17 September, 2004, pp. 491–498. Aracne.

10.

Neale

Tribology handbook. 1 ed. Oxford: The Butterworth group, 1973.

11.

Mulders

Frederik

Diepeveen

Control design, implementation, and evaluation for an in-field 500 kW wind turbine with a fixed-displacement hydraulic drivetrain.

Wind Energ Sci 2018; 3: 615–638.

12.

Glavatskih

Höglund

Tribotronics-towards active tribology. Tribol Int 2008; 41: 934–939.

13.

Tůma

Šimek

Škuta , et al. Active vibration control of hydrodynamic journal bearings. J Springer Proc Physics 2011; 139: 425–431.

14.

Rehman

Jiang

Luo

, et al. Control of active lubrication for hydrostatic journal bearing by monitoring bearing clearance. Adv Mech Eng 2018; 10: 168781401876814–17.

15.

Deckler

Veillette

Braun

, et al. Simulation and control of an active tilting-pad journal bearing. Tribol Trans 2004; 47: 440–458.

16.

Varela

Santos

IF.

Tilting-pad journal bearings with active lubrication applied as calibrated shakers: theory and experiment. J Vibr Acoust Trans ASME 2014; 136: 1–11.

17.

Van Ostayen

Van Beek

Ros

A parametric study of the hydro-support. Tribol Int 2004; 37: 617–625.

18.

Van Beek

Segal

Rubber supported hydrostatic thrust bearings with rigid bearing surfaces. Tribol Int 1997; 30: 47–52.

19.

Howell

Compliant mechanisms. Hoboken, NJ: Wiley & Sons, 2001.

20.

Jackson

Lei

Hydrodynamically lubricated and grooved biomimetic self-Adapting surfaces. J Funct Biomater 2014; 5: 78–98.

21.

Duvvuru

Jackson

Hong

JW.

Self-adapting microscale surface grooves for hydrodynamic lubrication. Tribol Trans 2008; 52: 1–11.

22.

Jackson

RL.

Self adapting mechanical step bearings for variations in load. Tribol Lett 2005; 20: 11–20.

23.

Fesanghary

Khonsari

MM.

On the shape optimization of self-adaptive grooves. Tribol Trans 2011; 54: 256–264.

24.

Fesanghary

Khonsari

MM.

On the modeling and shape optimization of hydrodynamic flexible-pad thrust bearings. Proc IMechE, Part J: J Engineering Tribology 2013; 227: 548–558.

25.

Downson

A generalized Reynolds equation for fluid-film lubrication. Int J Mech Sci 1962; 4: 159–170.

26.

Balcerzak

Raynor

Solutions for several shapes of externally pressurized hydrostatic thrust bearing. Appl Sci Res 1962; 11: 189–217.

27.

Rowe

WB.

Hydrostatic, aerostatic and hybrid bearing design. 1st ed. Amsterdam: Elsevier, 2013.

28.

Aurelian

Bonneau

Finite element method for fluid film bearings. In: Jane Wang Q and Chung YW (eds) Encyclopedia of tribology. Berlin: Springer, 2013, pp.34–109.

29.

Hamrock

Anderson

WJ.

Rayleigh step journal bearing, part II-Incompressible fluid. J Lubr Technol 1969; 91: 641–650.

30.

van Beek

Advanced engineering design lifetime performance and reliability. 6th ed. Netherlands: TU Delft, 2015.

31.

Heinrichson

On the Design of Tilting-Pad Thrust Bearings. PhD dissertation, Technical University of Denmark, 2007.

32.

Kuppens

Herder

Tolou

Permanent stiffness reduction by thermal oxidation of silicon. J Microelectromech Syst 2019; 28: 900–909.

33.

Liu

Zhao

, et al. Thermal characteristics of water-lubricated ceramic hydrostatic hydrodynamic hybrid bearings. Tribol Lett 2016; 63: 1–10.

34.

Laukiavich

Braun

Chandy

AJ.

An investigation into the thermal effects on a hydrodynamic bearing’s clearance. Tribol Trans 2015; 58: 980–1001.

35.

Chalkiopoulos

Charitopoulos

Fillon

, et al. Effects of thermal and mechanical deformations on textured thrust bearings optimally designed by a THD calculation method. Tribol Int 2020; 148: 106303.

36.

Harris

Edge

Tilley

DG.

Predicting tlie beliavior of slipper pads in swashplate-type axial piston pumps. J Dyn Syst Measure Control Trans ASME 1996; 118: 41–47.

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