The High Temperature Oxidation Behavior of Hot-Dipping Al Coating on 0Cr18Ni10Ti Stainless Steel

Jin Lou; Jie Ke Wang; Yu Bin Wang

doi:10.4028/www.scientific.net/AMR.905.123

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 905The High Temperature Oxidation Behavior of...

The High Temperature Oxidation Behavior of Hot-Dipping Al Coating on 0Cr18Ni10Ti Stainless Steel

Abstract:

0Cr18Ni10Ti stainless steel was coated by hot-dipping in a molten aluminum bath, and then diffusing annealing at 950°C for 2h. The high temperature isothermal oxidation behaviors of the hot-dipped aluminized steel and 0Cr18Ni10Ti steel were tested at 900 °C for 24h using Thermo gravimetric analyzer. The high temperature cyclic oxidation behaviors of the hot-dipped aluminized steel and 0Cr18Ni10Ti steel were tested at 900 °C for 24h using resistance furnace. The morphology was studied by SEM, the phase composition was characterized by EDS. The result of high temperature isothermal and cyclic oxidation test showed that the hot-dipped aluminum can dramatically improve the isothermal and cyclic oxidation of the 0Cr18Ni10Ti steel. The hot-dipping aluminum coating is consists of an outer layer of FeAl and an inner Iron solid solution with aluminum, after diffusion annealing at 950°C for 2 h. The Al2O3 oxide layer was formed on the hot-dipped aluminum coating during isothermal and cyclic oxidation process, which provides an additional protection for the steel from high temperature oxidation.

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Periodical:

Advanced Materials Research (Volume 905)

Pages:

123-127

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.905.123

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Online since:

April 2014

Authors:

Jin Lou, Jie Ke Wang, Yu Bin Wang

Keywords:

0Cr18Ni10Ti Stainless Steel, High Temperature Oxidation Resistance, Hot-Dipping Aluminum

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References

[1] Yang shi-wei, Wu jin-wei, Cui li-ping: Journal of Harbin Engineering University, Vol. 24(2003): 198-200.

Google Scholar

[2] Zhao Xia, Dang Zheng-qian, Cheng Ling: Surface Technology, Vol. 38(2009): 10-11.

Google Scholar

[3] Chaur-Jeng, Shi-Ming Chen: Surface and coatings technology, 200(2006): 6601-6605.

Google Scholar

[4] Wei-Jen Cheng, Chaur-Jeng Wang: surface and coatings technology, Vol. 204( 2009): 824-826.

Google Scholar

[5] DepingWang, Ziyuan Shi: Applied Surface Science, Vol. 227(2004): 225-260.

Google Scholar

[6] Wei-Jen Cheng, Yi-Jhang, Char-Jeng Wang: Materials characterization, Vol. 82(2013): 58-65.

Google Scholar

[7] Awan GH, HasanFU: Mater Sci Eng A, Vol. 472(2008): 157-165.

Google Scholar

[8] Wei-Jen Cheng, Chaur-Jeng Wang: Applied Surface Science, Vol. 274 (2013): 258-265.

Google Scholar

[9] Wei-Jen Cheng, Chaur-Jeng Wang: Materials characterization, Vol. 69(2012): 63-70.

Google Scholar

[10] G. Eggeler, H. Vogel, J. Friedrich, H. Kaesche: Praktische Metallographie , Vol. 22 (1985) 163–170.

Google Scholar

[11] K. Bouche, F. Barbier, A. Coulet: Materials Science and Engineering A, Vol. 249 (1998) 167–175.

Google Scholar

[12] Zhao Xia, Xu Jia-wen, Sun Yong-xin: Heat treatment of metals, Vol. 34(2009): 76-79.

Google Scholar

[13] Neil Birks, Gerald H. Meier, Frederick S. Pettit: Introduction to High-Temperature Oxidation of Metals (Cambridge Press, England, 2006).

Google Scholar

[14] Li Mengjin, Sun Xiaofeng, Guan Hengrong: Corrosion science and protection technology, Vol. 15(2003): 67-71.

Google Scholar

[15] Wang bing, Lu chunyan, Sun chao: Corrosion science and protection technology, Vol. 14(2002): 7-11.

Google Scholar