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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 797Friction Evolution in Running-In of Sliding Wear...

Friction Evolution in Running-In of Sliding Wear of Cast Iron Processed in Gleeble

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Abstract:

As limited results were reported in terms of the evolution of sliding friction with growth of oxide layer in thickness during running-in, a pin-on-disc wear test was carried out in this study. 4.8Ni-1.5Cr cast iron as core layer and low carbon steel as outer layers, were thermo-mechanically processed via three different routes. For samples with lower hardness due to their predominantly austenitic or martensite retarded matrices, we found that initially rapid increase of thickness of oxide layer continually lowers the sliding friction. However, after the oxide layer was beyond a certain thickness, the sliding friction began to increase consecutively. After a fluctuation of friction caused by the break-down of oxide, a mild equilibrium wear with roughly constant friction followed.

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Advances in Abrasive Technology XVI

Info:

Periodical:

Advanced Materials Research (Volume 797)

Pages:

713-718

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.797.713

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Online since:

September 2013

Authors:

Qi Zhang, Zheng Yi Jiang, Dong Bin Wei, Guo Liang Xie, Jing Tao Han

Keywords:

Adhesion, Dry Sliding, Friction, Gleeble, Oxide Layer, Pin-On-Disc, Running-In, Thickness

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© 2013 Trans Tech Publications Ltd. All Rights Reserved

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[1] F.H. Stott and M.P. Jordan: Wear Vol. 250 (2001) p.391.

[2] R.Y. Lee and Z. Eliezer: Wear Vol. 95(2) (1984) p.165.

[3] T.F.J. Quinn: Tribology International Vol. 16(5) (1983) p.257.

[4] H.S. Kong, E.S. Yoon, and O.K. Kwon: Wear Vol. 181 (1995) p.325.

[5] D.J. Barnes, J.E. Wilson, F.H. Stott, and G.C. Wood: Wear Vol. 45(2) (1977) p.161.

[6] F.H. Stott and G.C. Wood: Tribology International Vol. 11(4) (1978) p.211.

[7] J. Jiang, F.H. Stott, and M.M. Stack: Wear Vol. 176(2) (1994) p.185.

[8] J.E. Wilson, F.H. Stott, and G.C. Wood: Proceedings of the Royal Society of London Series a-Mathematical Physical and Engineering Sciences Vol. 369(1739) (1980) p.557.

[9] H. So, D.S. Yu, and C.Y. Chuang: Wear Vol. 253(9-10) (2002) p.1004.

[10] R. Correa, A. Bedolla-Jacuinde, J. Zuno-Silva, E. Cardoso, and I. Mejia: Wear Vol. 267(1-4) (2009) p.495.

DOI: 10.1016/j.wear.2008.11.009

[11] G. Xie, H. Sheng, J. Han, and J. Liu: Materials & Design Vol. 31(6) (2010), p.3062.

[12] P.J. Blau: Tribology International Vol. 38(11-12) (2005) p.1007.

[13] F.H. Stott: Tribology International Vol. 31(1-3) (1998) p.61.

[14] H. So: Wear Vol. 184(2) (1995) p.161.

[15] H. So: Tribology International Vol. 29(5) (1996) p.415.

[16] D.A. Rigney: Annual Review of Materials Science Vol. 18 (1988) p.141.

[17] A. Bedolla-Jacuinde, R. Coffea, I. Mejia, J.G. Quezada, and W.M. Rainforth: Wear Vol. 263 (2007) p.808.

[18] C. Vergne, C. Boher, R. Gras, and C. Levaillant: Wear Vol. 260(9–10) (2006) p.957.

DOI: 10.1016/j.wear.2005.06.005