PREDICTING PITTING CORROSION RATE OF WELD NUGGET (STIR ZONE) OF FRICTION STIR WELDED DISSIMILAR JOINTS OF ALUMINIUM – MAGNESIUM ALLOYS

Authors

  • R.Kamal Jayaraj Centre for Materials Joining and Research (CEMAJOR), Department of Manufacturing Engineering, Annamalai University, Annamalai Nagar – 608 002, Tamil Nadu, India.
  • S. Malarvizhi Centre for Materials Joining and Research (CEMAJOR), Department of Manufacturing Engineering, Annamalai University, Annamalai Nagar – 608 002, Tamil Nadu, India.
  • V.Balasubramanian Centre for Materials Joining and Research (CEMAJOR), Department of Manufacturing Engineering, Annamalai University, Annamalai Nagar – 608 002, Tamil Nadu, India.

Keywords:

Friction stir welding, Dissimilar joint, Aluminium alloy, Magnesium alloy, Pitting corrosion rate, Response surface methodology

Abstract

Joining of Magnesium (Mg) and Aluminium (Al) alloys by fusion welding processes is very difficult due to formation of intermetallic compounds in weld metal. This problem could be overcome by friction stir welding (FSW) because of solid state welding conditions. However, Al/Mg dissimilar FSW joints are more prone to corrosion attack due to the formation of intercalated microstructure in weld nugget (stir zone). The limitation of low corrosion resistance restricts practical applications of these types of joints. In this investigation, an attempt has been made to develop an empirical relationship to predict the pitting corrosion rate of nugget region of friction stir welded dissimilar joints of AA6061 Al – AZ31B Mg alloys. Three important corrosion test parameters, namely, chloride ion concentration, pH value and exposure time are chosen as input parameters. Three factors, five level, central composite rotatable design matrix is used to minimize the number of experimental conditions. Response surface methodology is used to develop an empirical relationship. The developed relationship can be effectively used to predict the pitting corrosion rate of friction stir welded dissimilar joints of AA6061 Al – AZ31B Mg alloys at 95 % confidence level. The methodology adopted to develop the relationship is presented in this paper.

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References

Ebert T and Mordike B L (2001), “Magnesium: Properties-applications-potential”, Material Science and Engineering A, Vol. 302(1), 37−45.

Agnew S R Mehrotra P Lillo T M Stoica G M and Liaw P K (2005), “Texture evolution of five wrought magnesium alloys during route A equal channel angular extrusion: Experiments and simulations”, Acta Materialia, Vol. 53(11), 3135−3146.

Lee W B Yeon Y M and June S B (2003), “The mechanical properties related to the dominant microstructure in the weld zone of dissimilar formed Al joints by friction stir welding”, Journal of Material Science, Vol.38, 4183–91.

Paglia C S and Buchheit R G (2006), “Microstructure, microchemistry and environmental cracking susceptibility of friction stir welded 2219-T87”, Material Science and Engineering A, Vol. 429, 107–14.

Chang W S Kim H J Noh J S and Bang H S (2006), “The evaluation of weld ability for AZ31B-H24 and AZ91C-F Mg alloys in friction stir”, Key Engineering Materials, Vol. 321–323II, 1723–8.

Thomas W M Nicholas E D Needham J C Murch M G Temple smith P and Dawes C J (1991), “International Patent Application”, PCT/GB92/02203.

Paglia C S Carroll M C Pitts B C Reynolds T and Buchheit R G (2002), “Strength, corrosion and environmentally assisted cracking of a 7075-T6 friction stir weld”, Materials Science Forum, Vol. 396–402, 1677–1684.

Zettler R Silva A A M Rodrigues S Blanco A and Santos J F (2006), “Dissimilar Al to Mg alloy friction stir weld”, Advance Engineering Materials, Vol. 8, 415–21.

McLean A A Powell G L F Brown I H and Linton V M (2003), “Friction stir welding of magnesium Alloy AZ31B to aluminum alloy 5083”, Science and Technology of Welding and Joining, Vol. 8, 462–4.

Shiqematsu I Kwon Y J Suzuki K Imai T and Saito N (2003), “Joining of 5083 and 6061Aluminum Alloys by friction stir welding”, Materials Science Letters, Vol. 22, 353–6.

Sato Y S Park S H C Michiuchi M and Kokawa H (2004),“Constitutional liquation during dissimilar friction stir welding of Al and Mg alloys”, Scripta Materialia, Vol. 50, 1233–6.

Somasekharan A C Murr L E (2004), “Microstructures in friction-stir welded dissimilar magnesium alloys and magnesium alloys to 6061-T6 aluminum alloy”, Materials Characterization, Vol. 52, 49–64.

Kostka A Coelho R S Dos Santo J and Pyzalla A R (2009), “Microstructure of friction stir welding of aluminium alloy to magnesium alloy”, Scripta Materialia, Vol. 60, 953–956.

Somasekharan A C and Murr L E (2004), “Microstructures in friction-stir welded dissimilar magnesium alloys and magnesium alloys to 6061-T6 aluminum alloy”, Materials Characterization, Vol. 52, 49– 64.

Simoncini M and Forcellese A (2012), “Effect of the welding parameters and tool configuration on micro- and macro-mechanical properties of similar and dissimilar FSWed joints in AA5754 and AZ31 thin sheets”, Materials and Design, Vol. 41, 50–60.

Seetharaman R Ravisankar V and Balasubramanian V (2014), “Effect of immersion time on the corrosion behavior of friction stir welded AA2024 aluminium alloy welds”, Journal of Manufacturing Engineering, Vol. 9(3), 143-148.

Khuri A I and Cornell J A (1996), “Response Surfaces”, Design and Analysis, New York, Marcel Dekker Ltd., 405.

Miller R G Freund J E and Johnson D E (1999), “Probability and Statistics for Engineers”, New Delhi, Prentice of Hall of India Pvt Ltd., 658.

Deshpande K B (2010), “Validated numerical modeling of galvanic corrosion for couples: Magnesium alloy (AE44)–mild steel and AE44–aluminium alloy (AA6063) in brine solution”, Corrosion Science, Vol.52 (10), 3514-3522.

El-Dahshan M E Shams El Din A M Haggag H H (2002), “Galvanic corrosion in the systems titanium/316L stainless steel/Al copper in Arabian water”, Desalination, Vol.142(2), 161-169.

Szklarska-Smialowska Z (1999), “Pitting corrosion of aluminum”, Corrosion Science, Vol. 41, 1743-1767.

Hikmet Altun and Sadri Sen (2004), “Studies on the influence of chloride ion concentration and pH on the corrosion and electrochemical behaviour of AZ63 magnesium alloy”, Materials and Design, Vol.25, 637–643.

Song G Johannesson B Hapugoda S and StJohn D (2004), “Galvanic corrosion of magnesium alloy AZ91D in contact with an aluminum alloy, steel and zinc”, Corrosion Science, Vol.46, 955–977.

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Published

2016-12-01

How to Cite

[1]
“PREDICTING PITTING CORROSION RATE OF WELD NUGGET (STIR ZONE) OF FRICTION STIR WELDED DISSIMILAR JOINTS OF ALUMINIUM – MAGNESIUM ALLOYS”, JME, vol. 11, no. 4, pp. 178–183, Dec. 2016, Accessed: Dec. 23, 2024. [Online]. Available: https://smenec.org/index.php/1/article/view/192

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