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Cast Iron Structures Produced by Laser Surface Melting and Alloying

Published online by Cambridge University Press:  21 February 2011

I. Hawkes
Affiliation:
Department of Metallurgy & Materials Science, Imperial College of Science and Technology, London SW7, England
L. Lundberg
Affiliation:
Department of Metallurgy & Materials Science, Imperial College of Science and Technology, London SW7, England
A. M. Walker
Affiliation:
Department of Metallurgy & Materials Science, Imperial College of Science and Technology, London SW7, England
W. M. Steen
Affiliation:
Department of Metallurgy & Materials Science, Imperial College of Science and Technology, London SW7, England
D. R. F. West
Affiliation:
Department of Metallurgy & Materials Science, Imperial College of Science and Technology, London SW7, England
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Extract

Laser surface melting and alloying provide a flexible route for modifying surface structures and properties. Potential technological benefits include improvement of properties such as resistance to corrosion and wear. The technique can also be used to obtain basic structural information for materials solidified over a range of rapid solidification rates. Laser surface melting of cast irons has been quite widely investigated [e.g. 1–4] using various initial structural states, including flake and spheroidal graphite irons; substantial surface hardening has been achieved from the white iron structures resulting from the rapid solidification. In the field of laser surface alloying a number of investigations have used ferrous substrates [5–9].

Type
Research Article
Copyright
Copyright © Materials Research Society 1985

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References

REFERENCES

1. Hawkes, I.C., Steen, W.M. and West, D.R.F., Proc. Conf. Lasers in Manufacturing Industry, IFS Nov. 1983 Google Scholar
2. Ricciardi, G., Pasquini, F. and Rudilasso, S., Proc. Conf. Lasers in Manufacturing Industry, IFS Nov. 1983 Google Scholar
3. Megaw, J.H.P.C., Bransden, A.S., Bell, T. and Trafford, D.N.T., Met. Tech. 10, 69 (1983).Google Scholar
4. Bergmann, H.W. and Mordike, B.L., Z. Werkstofftechn., 14, 228 (1983).10.1002/mawe.19830140705Google Scholar
5. Draper, G.W., J. of Metals, June 1982, p. 24.10.2307/1268490Google Scholar
6. Gnanamuthu, D.S., Applications of Lasers in Materials Processing, Ed. Metzbower, E.A., ASM, Ohio 1979, p.177.Google Scholar
7. Mordike, B.L., Mordike, H.W. and Gross, N., Z. Werkstofftechn., 14, 253 (1983).10.1002/mawe.19830140803CrossRefGoogle Scholar
8. Walker, A.M., Steen, W.M. and West, D.R.F., Met. Tech. (in the press).Google Scholar
9. Walker, A.M., Flower, H.M. and West, D.R.F., J. Mat. Sc (in the press).Google Scholar
10. Henry, P., Chande, T., Lipscombe, K., Mazumder, J. and Steen, W.M., Proc. ICALEO, Boston '82, 31, p. 25.Google Scholar
11. Hawkes, I.C., Lamb, M., Steen, W.M. and West, D.R.F., 3rd Int. Coll. On Welding and Melting by Electrons and Laser Beams, Lyon 1983, p. 125.Google Scholar
12. Hillert, M. and Steinhauser, H., Jerkont Ann, 144, 520 (1966).Google Scholar
13. Hillert, M. and Sub-a-Rao, V.V., The Solidification of Metals (Iron & Steel Institute 1968), p.204.Google Scholar
14. Ibaraki, M., Okamoto, J. and Matsumoto, H., J. Jap. Inst. Met., 32, 396 (1968).10.2320/jinstmet1952.32.4_396CrossRefGoogle Scholar
15. Jones, H. and Kurz, W., Z. Metallk., 72, 792 (1981).Google Scholar
16. Brewer, L., Chipman, J. and Chang-, S.G., Metals Handbook, V8, ASM, 1973 p.407.Google Scholar