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Selection of Scuffing-Resistant Materials Under Lubricated, High-Speed Sliding

Published online by Cambridge University Press:  28 February 2011

J. J. Au ,
M. W. Corcoran  and
J.-Y. Yung
J. J. Au
Affiliation:
Sundstrand Corporation, Advanced Technology Group 4747 Harrison Avenue, Rockford, IL 61125-7002
M. W. Corcoran
Affiliation:
Sundstrand Corporation, Advanced Technology Group 4747 Harrison Avenue, Rockford, IL 61125-7002
J.-Y. Yung
Affiliation:
Sundstrand Corporation, Advanced Technology Group 4747 Harrison Avenue, Rockford, IL 61125-7002
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Abstract

The scuffing resistance of materials under lubricated high-speed sliding was analyzed based on the thermalelastic instability (TEl) model. The model was used to select and rank scuffing-resistant materials.

The scuffing resistance was also determined experimentally by the Falex 6 thrust washer wear tests. There was good agreement between the experimental results and the analytical predictions.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 140: Symposium S – New Materials Approaches to Tribology: Theory and Applications , 1988 , 443
Copyright
Copyright © Materials Research Society 1989

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References

1. Khonsari, M. M., “A Review of Thermal Effects in Hydrodynamic Bearings. Part II: Journal Bearings,” ASLE Trans., 30, No. 1, pp. 2633 (1987).CrossRefGoogle Scholar
2. Dufrane, K. F and Kannel, J. W., “Thermally Induced Seizures of Journal Bearings,” ASME Paper No. 88-Trib-22 (December 1988). To be published.Google Scholar
3. Sibley, L. B. and Allen, C. M., “Friction and Wear Behavior of Refractory Materials at High Sliding Velocities and Temperatures,” ASME Paper No. 61-Lub-15 (May 1961).Google Scholar
4. Barber, J. R., “Thermal Effects in Friction and Wear,” Dissertation, St. John's College, Cambridge University, England (1968).Google Scholar
5. Barber, J. R., “Thermoelastic Instabilities in the Sliding of Conforming Solids,” Proc Roy. Soc., Ser. A, 312, pp. 381391 (1969).Google Scholar
6. Barber, J. R., “The Influence of Thermal Expansion on the Friction and Wear Process,” Wear, 10, pp. 155159 (1967).Google Scholar
7. Dow, T. A. and Stockwell, R. D., ASME Trans., Ser. F, 261, p. 359 (1977).Google Scholar
8. Blok, H., “Theoretical Study of Temperature Rise at Surface of Actual Contact Under Oiliness Lubricating Conditions,” General Discussion on Lubrication, Inst. Mech. Eng., Vol. 2, pp. 222235 (1937).Google Scholar
9. Holm, R., “Calculation of the Temperature Development in a Contact Heated in the Contact Surface and Application to the Problem of the Temperature Rise in a Sliding Contact,” Journal of Applied Physics 19, pp. 362366 (1948).CrossRefGoogle Scholar
10. Holm, R., Electric Contacts(Springer-Verlag, Berlin/Heidelberg, 4th Ed., 1967).CrossRefGoogle Scholar
11. Jaeger, J. C., Proc. Roy Soc. N.S.W., 56, p. 203 (1942).Google Scholar
12. Carslaw, H. S. and Jaeger, J. C., The Conduction of Heat in Solids (Oxford Univ. Press, London ).CrossRefGoogle Scholar
13. Archard, J. R., “The Temperature of Rubbing Surfaces,” Wear, 2, pp. 438455 (1959).Google Scholar
14. Kuhlmann-Wilsdorf, D., “Flash Temperature Due to Friction and Joule Heat at Asperity Contacts,” Proc. Int. Conf. Wear of Materials, ASME, pp. 456462 (1985).CrossRefGoogle Scholar
15. Winer, W. O. and Ting, B.-Y., “Development of a Theory of Wear of Ceramics,” Report No. ORNLJSub/84-7802/1, Oak Ridge National Laboratory (July 1988).Google Scholar
16. Dow, T. A. and Burton, R. A., “Thermoelastic Instability of Sliding Contact in the Absence of Wear,” Wear, 19, pp. 315328 (1972).Google Scholar
17. Dow, T. A. and Burton, R. A., “The Role of Heat in the Initiation of Thermoelastic Instabilities of Rubbing Contact,” ASME Journal of Lubrication Technology, 95, pp. 7175 (1973).CrossRefGoogle Scholar
18. Dow, T. A., “Thermoelastic Instabilities in Sliding Contact,” (Dissertation, Northwestern University 1972).CrossRefGoogle Scholar
19. Dow, T. A. and Stockwell, R. D., “Experimental Verification of Thermoelastic Instabilities in Sliding Contact,” ASME Journal of Lubrication Technology, 99, pp. 359364 (1977).CrossRefGoogle Scholar
20. Burton, R. A., Nerliker, V. and Kilaparti, S. R., “Thermoelastic Instability in a Seal-like Configuration,” Wear, 24, pp. 177188 (1973).Google Scholar
21. Johnson, R. R. and Dow, T. A., “The Role of Thermoelastic Effects in the Scuffing Failure of Rolling/Sliding EHD Contacts,” (Final Report to Department of the Navy, North Carolina State University, August 1988).Google Scholar
22. Durkec, D. B., “Mechanical Aspects of Scuffing Failure of Concentrated Simple Sliding Contacts,” (Dissertation, Northwestern University 1978).Google Scholar
23. Burton, R. A., “Thermomechanical Effects in Sliding Wear,” Fundamentals of Tribology, Ed. by Suh, N. P. and Saka, N., (The MIT Press, Cambridge, MA, 1978) pp. 614640.Google Scholar
24. Tabor, B. J., “Failure of Thin Film Lubrication - An Expedient for the Characterization of Lubricants,” ASME Paper No. 80-C2/Lub-43 (1980).Google Scholar
25. Belinger, A. and deGee, A. W. J., “Thin Film Lubrication of Sliding Point Contacts of AISI 522100 Steel,” Wear, 28, pp. 103114 (1973).CrossRefGoogle Scholar
26. Soloman, G., “Failure Criteria in Thin Film Lubrication,” Wear, 36, No. 1, pp. 16 (1976).Google Scholar
27. Czichos, H., “Failure Criteria in Thin Film Lubrication, Investigation of the Different Stages of Film Failure,” Wear, 36, No. 1, pp. 1317 (1976).Google Scholar