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TECHNICAL PAPERS

Critical Structures of Metal Destruction Under the Process of Wear

[+] Author and Article Information
I. I. Garbar

Department of Mechanical Engineering, Ben-Gurion University of the Negev, P.O. Box 653, Beer-Sheva, 84105, Israel

J. Tribol 122(1), 361-366 (May 18, 1999) (6 pages) doi:10.1115/1.555359 History: Received January 28, 1999; Revised May 18, 1999
Copyright © 2000 by ASME
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References

Langford,  G., and Cohen,  M., 1969, “Strain Hardening of Iron by Severe Plastic Deformation,” Trans. ASM, 62, pp. 623–638.
Rack,  H. J., and Cohen,  M., 1970, “Strain Hardening of Iron-Titanium Alloys at Very Large Strains,” Mater. Sci. Eng., 6, pp. 320–326.
Langford,  G., Nagata,  P. K., Sober,  R. J., and Leslie,  W. C., 1972, “Plastic Flow in Binary Substitutional Alloys of BCC Iron—Effect of Wire Drawing and Alloy Content on Work Hardening and Ductility,” Metal. Trans. 3, pp. 1843–1849.
Garbar, I. I., and Skorynin, V. Yu., 1975, “Investigation of the Surface Layer Structure Under Friction,” Machine Science, 106–109 (in Russian).
Garbar,  I. I., and Skorynin,  V. Yu., 1975, “Metal Surface Layer Structure Formation Under Sliding Friction,” Wear, 51, pp. 327–336.
K.,  Kato, 1993, “Friction and Wear,” Mater. Sci. Technol., R. W. Cahn et al., ed., VCH, 6, pp. 635–680.
Hughes,  D. A., Dawson,  D. B., Korellis,  J. S., and Weingarten,  L. J., 1994, “Near Surface Microstructures Developing under Large Sliding Loads,” J. Mater. Eng. Perform., 3, No. 4, pp. 459–475.
Garbar,  I. I., 1997, “The Effect of Load on the Structure and Wear of Friction Pair Materials (Example of Low-Carbon Steel and Copper),” Wear, 205, pp. 240–245.
Bay,  B., Hansen,  N., Haghes,  D. A., and Kuhlmann-Wilsdorf,  D., 1992, “Evolution of F.C.C. Deformation Structures in Polyslip,” Acta Metall. Mater., 40, No. 2, pp. 205–219.
Rybin, V. V., 1986, Large Plastic Deformation and Failure of Metals (in Russian), Metallurgia, Moscow.
Kato, K., Kayaba, T., and Ono, Y., 1985, “Dislocation Density and Cell Structure Produced in the Subsurface Layer of Aluminum During Sliding Wear,” Proceedings, International Conference on Wear of Materials, K. Ludema, ed., ASME, New York, pp. 464–470.
Quinn,  T. F. J., 1994, “Oxidental Wear Modelling: Part II. The General Theory of Oxidental Wear,” Wear, 175, pp. 199–208.
Quinn, T. F. J., 1991, Physical Analysis for Tribology, Cambridge University Press.
Snyder,  R. L., 1992, “X-Ray Diffraction,” Mater. Sci. Technol., R. W. Cahn et al., ed., VCH, 2A, pp. 251–356.

Figures

Grahic Jump Location
Correspondence between fragment dimensions of low-carbon steel and wear rate
Grahic Jump Location
Electron diffraction patterns of low-carbon steel wear products: (a) pressure 0.3 MPa; (b) pressure 3.3 MPa
Grahic Jump Location
Wear rate of aluminum and copper specimens, as a function of abrasive grit size
Grahic Jump Location
Structural broadening of the diffraction lines (400) Al and (331) Cu, as a function of abrasive grit size

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