Friction Changes during Compression Tests Using Tool Rotation Technique

X. Ma; Matthew R. Barnett; Y.H. Kim

doi:10.4028/www.scientific.net/KEM.274-276.895

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Friction Changes during Compression Tests Using Tool Rotation Technique

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Key Engineering Materials (Volumes 274-276)

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895-900

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https://doi.org/10.4028/www.scientific.net/KEM.274-276.895

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October 2004

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X. Ma, Matthew R. Barnett, Y.H. Kim

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References

[1] X. Ma. Compression and extrusion of metals using rotating dies. PhD Thesis, Deakin University: Geelong. (2003).

Google Scholar

[2] X. Ma, M.R. Barnett and Y.H. Kim: Key Engineering Materials Vol. 233-236 (2003), p.767.

Google Scholar

[3] X. Ma, M.R. Barnett and Y.H. Kim: International Journal of Mechanical Sciences Vol. 45 (2003), p.1717.

Google Scholar

[4] E.L. Francis, H. Greenwood and F.C. Thompson: Iron Steel Inst. -Carnegie Schol. Mem. Vol. 22 (1933), p.15.

Google Scholar

[5] X. Ma, M.R. Barnett and Y.H. Kim: International Journal of Mechanical Sciences, accepted.

Google Scholar

[6] R.Z. Valiev, R.K. Islamgaliev and I.V. Alexandrov: Progress in Materials Science Vol. 45 (2000), p.103.

Google Scholar

[7] Y.H. Kim, X. Ma, M.R. Barnett and P.D. Hodgson: Materials Science Forum Vol. 426-432 (2003), p.2777.

Google Scholar

[8] W. Linicus and G. Sachs: Mitt. dr. Mater. Anst. Vol. 16 (1931), p.38.

Google Scholar

[9] J.A. Schey. Metal deformation processes: Friction and lubrication, Marcel Dekker Inc.: New York, (1970).

Google Scholar

[10] B.P. Pedersen, T. Wanheim and N. Bay: International Conference on Forging and Related Technology. IMechE: UK, p.253. (1998).

Google Scholar

[11] L.X. Kong and P.D. Hodgson: Materials Science and Engineering Vol. A276 (2000), p.32.

Google Scholar