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Evaluation of Sulfidation Resistance of Atomized Fe40Al Based Intermetallics

Published online by Cambridge University Press:  31 January 2012

M. A. Espinosa-Medina ,
G. Carbajal de la Torre ,
A. Martínez-Villafañe  and
J.G. González-Rodríguez
M. A. Espinosa-Medina*
Affiliation:
Facultad de Ingeniería Mecánica, UMSNH, C.P. 58000, Morelia, Mich., México.
G. Carbajal de la Torre
Affiliation:
Facultad de Ingeniería Mecánica, UMSNH, C.P. 58000, Morelia, Mich., México.
A. Martínez-Villafañe
Affiliation:
CIMAV, Complejo Industrial Chihuahua, Chihuahua. México.
J.G. González-Rodríguez
Affiliation:
UAEM-CIICAP, Av. Universidad 1001, Col. Chamilpa, Cuernavaca, Morelos, México.
*
*Email: marespmed@gmail.com
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Abstract

The isothermal oxidation-sulfidation of Fe-40Al based intermetallics alloys in N2/SO2 gas mixture at 625, 700 and 775°C were evaluated. Fe40Al, Fe40Al+0.1B, Fe40Al+0.1B+10Al2O3 alloys were produced by atomization and deposition. Isothermal gas exposition was reached during 48 hours. FeAl based alloys showed good sulfidation resistance, presenting both small weight gain and weight change fluctuations. At 625°C, the Fe40Al+0.1B alloy had the biggest weight gain; on the other hand the Fe40Al alloy exhibited the biggest sulfidation resistance. At 700 and 775°C, the Fe40Al+0.1B alloy presented the smallest weight gain, however Fe40Al alloy presented higher weight gain, that is to say, the smallest sulfidation resistance at those temperatures. The variation in the weight gain curves were discussed in terms of formation and detachment of sulfides, and by local attack on the alloy surface as the temperature increasing. The results are supplemented with characterization by SEM and analysis of X-rays dispersion.

Keywords

AlloyOxidationThermogravimetric analysis (TGA)CorrosionScanning electron microscopy (SEM)
Type
Articles
Information
MRS Online Proceedings Library (OPL) , Volume 1372: Symposium S3 – Structural and Chemical Characterization of Metal Alloys and Compounds—2011 , 2012 , imrc-1372-s3-p101
Copyright
Copyright © Materials Research Society 2012

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References

REFERENCES

1. High-Temperature Corrosion in Gases Metals Handbook Ninth Edition, Vol. 13, Corrosion, edited by Cramer, Stephen D. and Covino, Bernard S., (ASM International, 1987) p.97.Google Scholar
2. Grzesik, Z., Mrowec, S., Corrosion Science, 50, 605 (2008)Google Scholar
3. Natesan, K., Materials at High Temperatures, 14, 71 (1997)Google Scholar
4. Patnaik, P. C. and Smeltzer, W. W., J. Electrochemical Society, 132, 1226 (1985)Google Scholar
5. Smith, P. J. and Smeltzer, W. W., Oxidation of Metals, 28, 291 (1987)Google Scholar
6. Mrowec, S., Oxidation of Metals, 44, 177 (1995)Google Scholar
7. Tortorelli, P. F. and Natesan, K., Materials Science and Engineering, A258, 115 (1998)Google Scholar
8. Natesan, K. and Johnson, R. N., Proceedings of the 2nd International Conf. on Heat-Resistant Materials, Tennessee, Sept. (1995) 591599.Google Scholar
9. Natesan, K. and Tortorelli, P. F., in: Deevi, S. C. et al. . (Eds.), International Symposium on Nickel and Iron Aluminides: Processing, Properties, and Applications, (ASM International, Materials Park, OH 1997) p.265 Google Scholar
10. DeVan, J. H., in: “Oxidation of Intermetallics” Edited by Grobstein, T., Doychak, J. (The Minerals, Metals, and Materials Society, Warrendale, PA, 1989) p.107 Google Scholar
11. DeVan, J. H. and Tortorelli, P. F., Corrosion Science, 35, 1065 (1993)Google Scholar
12. Natesan, K., Materials Science and Engineering, A258, 126 (1998)Google Scholar
13. Schutze, M. and Noth, M., in: Protective Coatings for High Temperatures and High Sulphur-Low Oxygen Environments” (Corrosion/98, NACE International, Houston, TX, 1988), paper No.188.Google Scholar
14. Martinez, L., Flores, O., Amaya, M., Duncan, A., Viswanathan, S., Lawrynowics, D. and Lavernia, E. J., J. of Materials Synthesis and Processing, 5, 65 (1997)Google Scholar
15. Espinosa-Medina, M.A., Liu, H.B., Canizal, G., and Ascencio, J.A., Materials Science and Engineering, A 443, 87 (2007)Google Scholar
16. Sauthoff, G., Materials Corrosion, 47, 587 (1996)Google Scholar
17. Deevi, S.C. and Sikka, V.K., Intermetallics, 4, 357 (1996)Google Scholar
18. Deevi, S.C., Sikka, V.K. and Liu, C.T., Prog. Materials Science, 42, 177 (1997)Google Scholar
19. Yamaguichi, M., Inui, H. and Ito, K., Acta Materialia, 48, 307 (2000)Google Scholar
20. Norton, J. F., Levi, T. P. and Bakker, W. T., Proceedings of the 2nd International Conf. on Heat-Resistant Materials, Tennessee, Sept. (1995) 111120 Google Scholar
21. Luer, K. R., DuPont, J. N. and Marder, A. R., Corrosion, 56, 189 (2000)Google Scholar
22. DeVan, J. H. and Tortorelli, P. F., Materials at High Temperatures, 11, 30 (1993)Google Scholar
23. Kai, W., Lee, S. H., Chiang, D. L., Chu, J. P., Materials Science and Engineering, A258, 146 (1998)Google Scholar
24. Espinosa-Medina, M.A., Casales, M., Martinez-Villafañe, A., Porcayo-Calderón, J., Izquierdo, G., Martínez, L. and González-Rodríguez, J.G., J. Materials Engineering and Performance, 9, 638 (2000)Google Scholar