Details
Title
Hot Dipping of Chromium Low-alloyed Steel in Al and Al-Si Eutectic Molten BathsJournal title
Archives of Foundry EngineeringYearbook
2021Volume
vo. 21Issue
No 1Affiliation
Attia, G.M. : Metallurgical and Materials Engineering Department, Faculty of Petroleum and Mining Engineering Suez University, Egypt ; Afify, W.M.A. : Metallurgical and Materials Engineering Department, Faculty of Petroleum and Mining Engineering Suez University, Egypt ; Ammar, M.I. : Metallurgical and Materials Engineering Department, Faculty of Petroleum and Mining Engineering Suez University, EgyptAuthors
Keywords
Coating ; Hot dipping ; Aluminizing ; Chromium low alloyed steelDivisions of PAS
Nauki TechniczneCoverage
37-50Publisher
The Katowice Branch of the Polish Academy of SciencesBibliography
[1] Kuruveri, U.B., Huilgol, P., Joseph, J. (2013). Aluminising of mild steel plates. ISRN Metallurgy. 1-6.[2] Isiko, M.B. (2012). A luminizing of plain carbon steel: Effect of temperature on coating and alloy phase morphology at constant holding time. Norway. Institute for material technology. 1-2.
[3] Davis, J.R. (1990). Surface engineering. vol. 5 of ASM Metals Handbook. Ohio, USA Materials Park.
[4] Ahmad, Z. (2006). Principles of corrosion engineering and corrosion control. London: UK. Elsevier. 17.
[5] Burakowski T., Weirzchok, T. (2000). S urface engineering of Metals- Principles, Equipments, Technologies. CRC Press, London, UK.
[6] Pattankude1, B.G., Balwan,. A.R. (2019). A review on coating process. International Research Journal of Engineering and Technology (IRJET). 06(3), 7980.
[7] Huilgol, P., Bhat, S. & Bhat, K.U. (2013). Hot-dip aluminizing of low carbon steel using Al- 7Si-2Cu alloy baths. Journal of Coatings. 2013, 1-6.
[8] Lin, M.-B. Wang, C.-J. & Volinsky, A.A. (2011). Isothermal and thermal cycling oxidation of hot- dip aluminide coating on flake/spheroidal graphite cast iron. Surface and Coatings Technology. 206, 1595-1599.
[9] Dngik Shin, Jeong-Yong Lee, Hoejun Heo, & Chung-Yun Kang. (2018). Formation procedure of reaction phases in Al hot dipping process of steel. Metals journal. 1.
[10] Yu Zhang, Yongzhe Fan, Xue Zhao, An DU, Ruina Ma, & Xiaoming Cao. (2019). Influence of graphite morphology on phase, microstructure and properities of hot dipping and diffusion aluminizing coating on flake/spheroidal graphite cast iron. Metals journal. 1.
[11] Voudouris, N. & Angelopoulos, G. (1997). Formation of aluminide coatings on nickel by a fluidized bed CVD process. Surface Modification Technologies XI. 558-567.
[12] Wang, D. & Shi, Z. (2004). Aluminizing and oxidation treatment of 1Cr18Ni9 stainless steel. Applied surface science. Volume (227). 255-260.
[13] Murakami, K., Nishida, N., Osamura, K. & Tomota, Y. (2004). Aluminization of high purity iron by powder liquid coating. Acta Materialia. 52(5), 1271-1281.
[14] Cheng, W.-J. & Wang, C.-J. (2013). High-temperature oxidation behavior of hot-dipped aluminide mild steel with various silicon contents. Applied surface science. 274. 258-265.
[15] Mishra, B., Ionescu, M. & Chandra, T. (2013). The effect of Si on the intermetallic formation during hot dip aluminizing. Advanced Materials Research. Volume 922, 429-434.
[16] Kee-Hyun, et. Al. (2006). Observations of intermetallic compound formation of hot dip aluminized steel. Materials Science Forum. 519-521, 1871-1875.
[17] Fry, A., Osgerby, S., Wright, M. (2002). Oxidation of alloys in steam environments. United Kingdom: NPL Materials Centre. 6.
[18] Scott, D.A. (1992). Metallography and microstructure in ancient and historic metals. London. Getty publications. 57-63.
[19] Lawrence J. Korb, Rockwell, David L. Olson. (1992). ASM Handbook Vol 13: Corrosion: Fundametals, Testing and Protection. Florida, USA: ASM International Handbook Committee.
[20] Nicholls, J. E. (1964). Corr. Technol. 11.16.
[21] Azimaee, H. et. al. (2019). Effect of silicon and manganese on the kinetics and morphology of the intermetallic layer growth during hot-dip aluminizing. Surface and Coatings Technology. 357. 483-496.
[22] Sun Kyu Kim, (2013). Hot-dip aluminizing with silicon and magnesium addition I. Effect on intermertallic layer thickness. Journal of the Korean Institute of Metals and Materials. 51(11), 795-799.
[23] Springer, H., Kostka, A., Payton, Raabe, D., Kaysser, A. & Eggeler, G. (2011). On the formation and growth of intermetallic phases during interdiffusion growth between low-carbon steel and aluminum alloys. Acta Materialia. 59, 1586-1600.
[24] Kab, M., Mendil, S. & Taibi, K. (2020). Evolution of the microstructure of intermetallic compounds formed on mild steel during hot dipping in molten Al alloy bath. M etallography, Microstructure and Analysis. Journal 4.
[25] Bahadur A. & Mohanty, O.N. (1991). Materials Transaction. JIM. 32(11), 1053-1061.
[26] Bouche, K., Barbier, F. & Coulet, A. (1998). Intermetallic compound layer growth between solid iron and molten aluminium. Materials Science and Engineering A. 249(1-2), 167-175.
[27] Maitra, T. & Gupta, S.P. (2002). Intermetallic compound formation in Fe–Al–Si ternary system: Part II. Materials Characterization. 49(4), 293-311.
[28] Nychka, J.A. & Clarke, D.R. (2005). Quantification of aluminum outward diffusion during oxidation of FeCrAl alloys. Oxidation of Metals. 63 (Nos.5/6), 325-351.
[29] Lars, P.H. et. All. (2002). Growth kinetics and mechanisms of aluminum-oxide films formed by thermal oxidation of aluminum. Journal of Applied Physics. 92(3), 1649-1656.
[30] Murray, J.L. (1992). Fe–Al binary phase diagram, in: H. Baker (Ed.), Alloy Phase Diagrams. ASM International. OH- USA. Materials Park. 54.