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On the Problems with Carbide Formation in Gray Cast Iron

Published online by Cambridge University Press:  21 February 2011

R. B. Gundlach
Affiliation:
AMAX Materials Research Center, Ann Arbor, MI, USA
J. F. Janowak
Affiliation:
Climax Molybdenum Co., Arlington Heights, IL, USA
S. Bechet
Affiliation:
AMAX Europe S.A., Paris, France
K. Rohrigtt
Affiliation:
Climax Molybdenum GmbH, Dusseldorf, W. Germany
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Extract

Gray iron technology has advanced greatly in the past half century. Much has been learned about the mechanisms of nucleation and solidification and about solid state transformations. This information has alloweu gray iron castings to remain competitive for structural components. Low cost and excellent castability make them versatile for a wide variety of industrial components including engine blocks, cylinder heads, housings, manifolds, hydraulic valve bodies and many other castings of similar complexity. Gray cast iron provides the technical advantages of high strength, soundness, good machinability, dimensional stability and uniformity of properties usually required by such cast components. Achieving these characteristics is dependent, however, on achieving proper and uniform structures tnrougnout all sections of the casting. This objective is reaoily attainable in judiciously alloyed gray cast iron.

Type
Research Article
Copyright
Copyright © Materials Research Society 1985

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References

REFERENCES

1. Annual Book of ASTM Standards, 1983, Vol. 01.02, Standard Specification for Gray Iron Castings, A 48–76, p. 21.Google Scholar
2. Schneidewind, R. and McElwee, R. G., AFS Trans., 58, 312332 (1950).Google Scholar
3. Olen, K. R. and Heine, R. W., AFS Trans., 76, 369 (1968).Google Scholar
4. Neumann, F., Schenck, H. and Patterson, W., Giesserei, 47, 2532 (Jan 1960).Google Scholar
5. Neumann, F. and Schenck, H., Giesserei, 14, No. 1, 2129 (1962).Google Scholar
6. Dawson, J. V., Official Exchange Paper – Great Britain, 49th International Foundry Congress, Chicago, IL (Apr 1982).Google Scholar
7. Oldfield, W., BCIRA Journal 10, No. 1, 1727 (Jan 1962).Google Scholar
8. Humphreys, J. G., BCIRA Journal 9, No. 5, 609631 (1961).Google Scholar
9. Heine, R. W., AFS Cast Metals Research Journal (Jun 1971).Google Scholar
10. Oldfield, W., BCIRA Journal 9, No. 4, 506518 (Jul 1961).Google Scholar
11. Merchant, H. D., Recent Research on Cast Iron, Proceedings of an ASM Seminar, Detroit, MI, Merchant, H. D., ed., Gordon and Breach, NY (Jun 1964).Google Scholar
12. Margerie, J. C., AFS Trans., 78, 281286 (1970).Google Scholar
13. “Heat Treatment Fundamentals of Nickel Alloy Cast Iron,” International Nickel Company (1938).Google Scholar
14. Janowak, J. F. and Gundlach, R. B., AFS Trans., 90, 847863 (1982).Google Scholar
15. Fuller, A. G., BCIRA Journal 5, 157170 (1957).Google Scholar
16. Merchant, H. D., AFS Trans., 70, 973992 (1962).Google Scholar
17. Gundlach, R. B. and Scholz, W. G., AFS Trans., 81, 395402 (1973).Google Scholar