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Mechanical And Metallurgical Characterisation Of Friction Stir Welded Aluminium Alloys AA5083-O And AA6061-T4

Kudzanayi Chiteka*, Narayana Yuvaraj**
*-** Production Engineering, Delhi Technological University, India.
Periodicity:April - June'2014
DOI : https://doi.org/10.26634/jms.2.1.2758

Abstract

This research presents the mechanical and metallurgical properties of dissimilar joints of AA5083-O and AA6061-T4 aluminum alloy. Two rotational speeds, 630 and 1600 rpm and three traverse speeds 16, 25, and 40 mm/min were applied to perform the joining process. Macrostructural observations were done to evaluate the weld quality and some semi-circular profiles appeared on the trailing side of the weld and flash were also visible on the retreating side of the joint. Optical microscopy was used to determine the orientation and distribution of the grains in the weld and the adjacent zones. Dynamic recrystallization was evident in the dissimilar joint and the fine grain structure confirmed this. The material in the stir zone contained a mixture of both materials but AA6061-T4 which was fixed on the advancing side dominated the stir zone and thus it influenced the joint performance. Mechanical properties of the joints i.e. ultimate strength, elongation, and microhardness were determined for different weld zones and material combinations. Material combinations included joints made of similar AA5083-O or AA6061-T4 as well as dissimilar joints of AA5083-O and AA6061-T4. The dissimilar joint exhibited intermediate mechanical properties. Hardness values were generally less in the advancing side compared to the retreating side and also they increased from the bottom towards the top of the joint.

Keywords

 Friction Stir Welding, Mechanical Characterisation, Macrostructure, Microstructure, Microhardness.

How to Cite this Article?

 Chiteka, K., & Yuvaraj, N. (2014). Mechanical and Metallurgical Characterisation of Friction Stir Welded Aluminium Alloys Aa5083-O And Aa6061-T4. i-manager's Journal on Material Science, 2(1), 7-14. https://doi.org/10.26634/jms.2.1.2758

References
[1]. R. Palanivel., P. Koshy Mathews, (2012). Prediction and optimization of process parameter of friction stir welded AA5083- H111 aluminum alloy using response surface methodology, J. Cent. South Univ. 19 1?8.
[2]. I. Shigematsu., Y.-J. Kwon., K. Suzuki., T. Imai., N. Saito., (2003). Joining of 5083 and 6061 aluminum alloys by friction stir welding, Journal Of Materials Science, Letters 22, 353– 356.
[3]. Y. K. Yousif., K. M. Daws., B. I. Kazem., (2008). Prediction of Friction Stir Welding Characteristic Using Neural Network, Jordan Journal of Mechanical and Industrial Engineering , Volume 2, Number 3, 151 – 155.
[4]. P.M.G.P. Moreira., T. Santos., S.M.O. Tavares., V. Richter- Trummer., P. Vilaça., P.M.S.T. de Castro., (2009). Mechanical and metallurgical characterization of friction stir welding joints of AA6061-T6 with AA6082-T6, Materials and Design, 30, 180–187.
[5]. M. Ghosh., K. Kumar., S.V. Kailas., A.K. Ray., (2010). Optimization of friction stir welding parameters for dissimilar aluminum alloys, Materials and Design, 31, 3033– 3037.
[6]. T. L. Dickerson, and J. Przydatek, (2003). Fatigue of friction stir welds in aluminum alloys that contain root flaws. Int. J. Fatigue, 25, 1399–1409.
[7]. P. Bahemmat., M. Haghpanahi., M.K. Besharati., S. Ahsanizadeh., H. Rezaei., (2010). Study on mechanical, micro-, and macrostructural characteristics of dissimilar friction stir welding of AA6061-T6 and AA7075-T6, Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 224: 1854.
[8]. Ákos Meilinger., Imre Török., (2013). The Importance of Friction Stir Welding Tool, Production Processes and Systems, Vol. 6. No. 1., pp. 25-34.
[9]. K. Colligan, (1999). Material Flow Behaviour During Friction Stir Welding of Aluminum, Supplement to the Welding Journal.
[10]. Hidetoshi Fujii., Ling Cui., Masakatsu Maeda., Kiyoshi Nogi., (2006). Effect of tool shape on mechanical properties and microstructure of friction stir welded aluminum alloys, Materials Science and Engineering, A 419, 25–31.
[11]. Min-Su Han., Seung-Jun Lee., Jae-Cheul Park., Seok- Cheol KO., Yong-Bin Woo., Seong-Jong Kim., (2009). “Optimum condition by mechanical characteristic evaluation in friction stir welding for 5083-O Al alloy”, Trans. Nonferrous Met. Soc. China 19 s17-s22.
[12]. R. Palanivel, P. Koshy Mathews, N. Murugan, I. Dinaharan, (2012). Effect of tool rotational speed and pin profile on microstructure and tensile strength of dissimilar friction stir welded AA5083-H111 and AA6351-T6 aluminum alloys, Materials and Design, 40, 7–16.
[13]. Damjan Klobcar., Ladislav Kosec., Adam Pietras., Anton Smolej., (2012). Friction-Stir Welding Of Aluminium Alloy 5083, Materials and technology 46 5, 483–488.
[14]. A. Heidarzadeh., H. Khodaverdizadeh., A. Mahmoudi., E. Nazari., (2012). Tensile behaviour of friction stir welded AA 6061-T4 aluminum alloy joints, Materials and Design, 37, 166–173.
[15]. I. Dinaharan., K. Kalaiselvan., S.J. Vijay, P. Raja., (2012). Effect of material location and tool rotational speed on microstructure and tensile strength of dissimilar friction stir welded aluminum alloys, Archives of civil and mechanical engineering, 12, 446 –454.
[16]. Won-Bae Lee., Yun-Mo Yeon., Seung-Boo Jung., (2003). The joint properties of dissimilar formed Al alloys by friction stir welding according to the fixed location of materials, Scripta Materialia, 49, 423–428.
[17]. S.T. Amancio-Filho., S. Sheikhi., J.F. dos Santos., C. Bolfarini., (2008). Preliminary study on the microstructure and mechanical properties of dissimilar friction stir welds in aircraft aluminium alloys 2024-T351 and 6056-T4, Journal of Materials Processing Technology, 206, 132–142.
[18]. Threadgill, P.L. (1999). Friction-Stir Welding-State of the Art, TWI, Report 678, England,
[19]. Bradly, G.R., and James, M.N. Geometry and Microstructure of Metal Inert Gas and Friction Stir Welded Aluminum Alloy 5383-H321, Report, and Oct.2000.
[20]. Rai, R., De, A., Bhadeshia H.K.D.H. & Debroy, T. (2011), Review: Friction stir welding tools, Science and Technology of Welding and Joining, Vol. 16, No. 4, p. 325.
[21]. Zhao, Y. H., Lin, S. B., Wu, L., and Qu, F.X. (2005). The influence of pin geometry on bonding and mechanical properties in friction stir weld 2014 Al alloy. Materials Letters 59: 2948–2952.
[22]. Hidetoshi, F., Ling, C., Masakatsu, M., Yutake, S. S., and Kiyoshi, N. (2006). Effect of threads on tool in friction stir welding of aluminium alloys. Materials Science Forum 512: 389–394.
[23]. G. Padmanaban, V. Balasubramanian, (2009). Selection of FSW tool pin profile, shoulder diameter and material for joining AZ31B magnesium alloy – An experimental approach, Materials and Design, 30, 2647–2656.
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