Influence of wall slip on the dynamic properties of a rotor-bearing system

Tribology Transactions

Volumn 51, Issue 2, 2008, Pages 204-212

  Ma, G J ^a   Wu, C W ^a   Zhou, P ^a  

^a DALIAN UNIVERSITY OF TECHNOLOGY   (China)

Author keywords

Journal Bearing; Load Carrying Capacity; Stability; Wall Slip

Indexed keywords

EID: 85020846279     PISSN: 10402004     EISSN: 1547397X     Source Type: Journal    
DOI: 10.1080/10402000801926539     Document Type: Article

References (35)

1. Hamrock, B. J. (1994), Fundamentals ofFluid Film Lubrication, McGraw-Hill Inc., New York.
2. Faber, T. (1995), Fluid DynamicsforPhysicists, Cambridge UniversityPress, Cambridge.
3. Schnell, E. (1956), “Slippage ofWaterOverNonwettable Surfaces,” J.Appl. Phys., 27, pp 1149-1152.
4. Churaev, N. V., Sobolev, V. D. and Somov, A. N. (1984), “Slippage ofLiquid over Lyophobic Solid Surfaces,” J. Colloid Interface Sci., 97, pp 574-581.
5. Pit, R., Hervet, H. and Leger, L. (2000), “DirectExperimentalEvidenceof Slip in Hexadecane: Solid Interfaces,” Phys. Rev. Lett., 85, pp 980-983.
6. Zhu, Y. X. and Granick, S. (2002), “Limits of the Hydrodynamic No-Slip Boundary Condition,” Phys. Rev. Lett., 88,106-102.
7. Baudry, J. and Charlaix, E. (2001), “Experimental Evidence for a Large Slip Effect at a Nonwetting Fluid-Solid Interface,” Langmuir, 17, pp 5232-5236.
8. Tretheway, D. C. and Meinhart, C. D. (2002), “Apparent Fluid Slip at Hydrophobic Microchannel Walls,” Phys. Fluids, 14, pp L9-L12.
9. Cottin-Bizonne, C., Cross, B., Steinberger, A. and Charlaix, E. (2005), “Boundary Slip on Smooth Hydrophobic Surfaces: Intrinsic Effects and Possible Artifacts,” Phys. Rev. Lett., 94, 056102.
10. Choi, C. H., Westin, K. J. A. and Breuer, K. S. (2003), “Apparent Slip Flows in Hydrophilic and Hydrophobic Microchannels,” Phys. Fluids, 15, pp 2897-2902
11. Zhu, Y. X. and Granick, S. (2001), “Rate-Dependent Slip of Newtonian Liquid at Smooth Surfaces,” Phys. Rev. Lett., 87, 096105.
12. Craig, V. S. J., Neto, C. and Williams, D. R. M. (2001), “Shear-Dependent Boundary Slip in an Aqueous Newtonian Liquid,” Phys. Rev. Lett., 87, 054504.
13. Bonaccurso, E., Kappl, M. and Butt, H. J. (2002), “Hydrodynamic Force Measurements: Boundary Slip of Hydrophilic Surfaces and Electrokinetic Effects,” Phys. Rev. Lett., 88, 076103.
14. Thompson, P A. and Troian, S. M. (1997), “A General Boundary Condition for Liquid Flow at Solid Surfaces,” Nature, 389, pp 360-362.
15. Barrat, J. L. and Bocquet, L. (1999), “Large Slip Effect at a Nonwetting Fluid-solid Surface,” Phys. Rev. Lett., 82, pp 4671-4674.
16. Priezjev, N. V., Darhuber, A. A. and Troian, S. M. (2005), “Slip Behavior in Liquid Films on Surfaces of Patterned Wettability: Comparison between Continuum and Molecular Dynamics Simulations,” Phys. Rev. E, 71, 041608.
17. Spikes, H. A. (2003), “The Half-Wetted Bearing. Part1: Extended Reynolds Equation,” Proc. Instn. Mech. Engrs. Part J: J. Eng. Tribol., 217, pp 1-14.
18. Spikes, H. A. (2003), “The Half-Wetted Bearing. Part 2: Potential Application in Low Load Contacts,” Proc. Instn. Mech. Engrs. Part J: J. Eng. Tribol., 217, pp 15-26.
19. Wu, C. W. and Ma, G. J. (2005), “Abnormal Behavior of a Hydrodynamic Lubrication Journal Bearing Caused by Wall Slip,” Tribol. Int., 38, pp 492-499.
20. Wu, C. W., Zhou, P and Ma, G. J. (2006), “Squeeze Fluid Film of Spherical Hydrophobic Surfaces with Wall Slip,” Tribol. Int., 39, pp 863-872.
21. Wu, C. W., Ma, G. J. and Zhou, P (2006),“Low Friction and High Load Support Capacity for Slider Bearing with a Mixed Slip Surface,” ASME J. Tribol., 128, pp 904-907.
22. Salant, R. F. and Fortier, A. E. (2004), “Numerical Analysis of a Slider Bearing with a Heterogeneous Slip/No-Slip Surface,” Tribol. Trans., 47, pp 328-334.
23. Fortier, A. E. and Salant, R. F. (2005), “Numerical Analysis of a Journal Bearing with a Heterogeneous Slip/No-Slip Surface,” J. Tribol., 124, pp 820-825.
24. Navier, C. L. M. H. (1823), Memoires de l’ Academie Royale des Sciences de l’Institut de France, 1, pp 414-416.
25. Maxwell, J. C. (1879), “On Stresses in Rarified Gases Arising from Inequalities of Temperature,” Philos. Trans. R. Soc. Lond., 170, pp 231-256.
26. Bair, S. and Winer, W. O. (1979), “Shear Strength Measurements of Lubricants at High Pressure,” ASME J. Lub. Tech., 101, pp 251-256.
27. Bair, S. and Winer, W. O. (1992), “The High Pressure High Shear Stress Rheology ofLiquid Lubricants,” ASME J. Tribol., 114, pp 1-13.
28. Hoglund, E. (1989), “The Relation between Lubricant Shear Stress Strength Analyzer and Chemical Composition of the Base Oil,” Wear, 130, pp 213-224.
29. Wikstrom, V. and Hoglund, E. (1994), “Investigation of Parameter Affecting the Limiting Shear Stress-Pressure Coefficient: A New Model Incorporating Temperature,” ASME J. Tribol., 116, pp 612-620.
30. Wu, C. W. and Sun, H. X. (2006), “Quadratic Programming Algorithm for Wall Slip and Free Boundary Pressure Condition,” Int. J. Numer. Meth. Fluids, 50, pp 131-145.
31. Ma, G. J., Wu, C. W. and Zhou, P (2007), “Multi-linearity Algorithm for Wall Slip in Two-Dimensional Gap Flow,” Int. J. Numer. Meth. Eng., 69, pp 2469-2484.
32. Zhang, Z. M., etal. (1986), Theory of Hydrodynamic Lubrication of Sliding Bearing (In Chinese), Higher Education Press, Beijing.
33. Mokhtar, S. B., Hanif, D. S. and Shetty, C. M. (1993), Nonlinear Programming: Theory and Algorithms, 2nd ed., John Wiley & Sons, New York.
34. Lund, J. W. and Thomson, K. K. (1978), “A Calculation Method and Data for the Dynamic Coefficients of Oil-Lubricated Journal Bearing,” Topics in Fluid Journal Bearing and Rotor Bearing System, ASME, New York, pp 128.
35. Ma, G. J., Wu, C. W. and Zhou, P (2007), “Wall Slip and Hydrodynamics of Two-Dimensional Journal Bearing,” Tribol. Int., 40, pp 1056-1066.