Experimental investigations of friction stir welded AA6063 aluminum matrix composite

Authors

  • Narinder Kaushik Department of Mechanical Engineering National Institute of Technology, Kurukshetra, Haryana – 136119, India
  • Sandeep Singhal Department of Mechanical Engineering National Institute of Technology, Kurukshetra, Haryana – 136119, India
  • Rajesh Rajesh Department of Mechanical Engineering National Institute of Technology, Kurukshetra, Haryana – 136119, India
  • Pardeep Gahlot Department of Mechanical Engineering UIET, MDU, Rohtak, Haryana-124001, India
  • B. N Tripathi Department of Mechanical Engineering Lingayas Vidyapeeth, Faridabad, Haryana-121002, India

DOI:

https://doi.org/10.15282/jmes.12.4.2018.11.0357

Keywords:

Friction stir welding, Aluminum matrix composites, AA6063, microstructure, microhardness, ultimate tensile strength

Abstract

The advancement of friction stir welding for joining of aluminum alloys and aluminum centered matrix composite has replaced the traditional welding techniques. In this experimental study, AA6063/10.5wt%SiC composite has been produced by employing enhanced stir casting technique with the assistance of Mg metal powder. Specimen composite plates having thickness 6 mm were friction stir welded successfully. The impact of welding variables on mechanical and microstructural characteristics of weldments has been studied. The friction stir welding (FSW) was carried out at a rotation rate of tool of 1400 rpm with a tool transverse rate of 124 mm/min. A cylindrical tool fabricated of high-speed steel (HSS) with square pin shape has been used for FSW. The results revealed that the ultimate tensile strength of the welded joint was 163 MPa, which was very close to the strength of the as-cast composite matrix. The microstructural study showed the reason for higher joint strength and microhardness. The welded butt joint exhibited a change in the microstructure at various four welding zones which transforms the mechanical characteristics of welded joints has been due to the asymmetrical flow of material and thermal cycles around the pin. The intense stirring action of the tool pin during FSW cracked the SiC particles in the weld nugget.  In the weld region, a fine-grained structure and homogeneous dispersion of SiC particles have been observed. The micro porosities associated with the base metal composite matrix were eliminated after FSW.

References

Maleque MA, Radhi M, Rahman MM. Wear study of Mg-SiCp reinforcement aluminium metal matrix composite. Journal of Mechanical Engineering and Sciences. 2016; 10: 1758-64.

Khan MM, Dixit G. Erosive wear response of SiCp reinforced aluminium based metal matrix composite: Effects of test environments. Journal of Mechanical Engineering and Sciences. 2017; 14: 2401-14.

Kaushik Narinder, Singhaal, Sandeep. Mechanical and Metallurgical Examinations of Stir Cast Aluminum Matrix Composites: A Review Study. International Journal of Engineering and Technology. 2017; 9: 3203-3217.

Sajjadi SA, Ezatpour HR, Parizi MT. Comparison of microstructure and mechanical properties of A356 aluminum alloy/Al2O3 composites fabricated by stir and compo-casting processes. Materials & Design. 2012; 34:106–11.

Kaushik N, Singhal S. Examination of Wear Properties in Dry-Sliding States of SIC Strengthened Al-Alloy Metal Matrix Composites by Using Taguchi Optimization Approach. International Journal of Applied Engineering Research. 2017; 12(20): 9708-9716.

Dinaharan I, Murugan N. Optimization of friction stir welding process to maximize tensile strength of AA6061/ZrB2 in situ composite butt joints. Metals and Materials International, 2012; 18:135–42.

Prater T. Solid-state joining of metal matrix composites: a survey of challenges and potential solutions. Materials and Manufacturing Processes. 2011; 26:636–48.

Storjohann D, Barabash OM, Babu SS, David SA, Sklad PS, Bloom EE. Fusion and friction stir welding of aluminum–metal–matrix composites. Metall Mater Trans A. 2005; 36:3237–47

Guo J, Gougeon P, Chen XG. Study on laser welding of AA1100-16 vol.% B4C metal–matrix composites. Composites Part B. 2012; 43:2400–8.

Xi-he W, Ji-tai N, Kang GS, Le-jun W, Feng CD. Investigation on TIG welding of SiCp-reinforced aluminum–matrix composite using mixed shielding gas and Al–Si filler. Material Science and Engineering: A. 2009; 499:106–10.

Wang SG, Ji XH, Zhao XQ, Dong NN. Interfacial characteristics of electron beam welding joints of SiCp/Al composites. Material Science and Technology. 2011; 27:60-64.

Cam G. Friction stir welded structural materials: beyond Al-alloys. International Materials Reviews. 2011; 56:1-48.

Threadgill PL, Leonard AJ, Shercliff HR, Withers PJ. Friction stir welding of aluminium alloys. International Materials Reviews. 2009; 54:49–93.

Chen XG, Da Silva M, Gougeon P, St-Georges L. Microstructure and mechanical properties of friction stir welded AA6063–B4C metal matrix composites. Material Science and Engineering: A. 2009; 518:174–84.

Vijay SJ, Murugan N. Influence of tool pin profile on the metallurgical and mechanical properties of friction stir welded Al–10 wt.% TiB2 metal matrix composite. Materials & Design. 2010; 31:3585–9.

Nami H, Adgi H, Sharifitabar M, Shamabadi H. Microstructure and mechanical properties of friction stir welded Al/Mg2Si metal matrix cast composite. Materials & Design. 2010; 32:976–83.

Gopalakrishnan S, Murugan N. Prediction of tensile strength of friction stir welded aluminum matrix TiCp particulate reinforced composite. Materials & Design. 2011; 32:462–7.

Guo J, Amira S, Gougeon P, Chen XG. Effect of the surface preparation techniques on the EBSD analysis of a friction stir welded AA1100-B4C metal matrix composite. Materials Characterization. 2011; 62:865–77.

Bozkurt Y, Uzun H, Salman S. Microstructure and mechanical properties of friction stir welded particulate reinforced AA2124/SiC/25p–T4 composite. Journal of Composite Materials. 2011; 45:2237–45.

Dinaharan I, Murugan N. Effect of friction stir welding on microstructure, mechanical and wear properties of AA6061/ZrB2 in situ cast composites. Material Science and Engineering: A. 2012; 543:257–66.

Guo J, Gougeon P, Chen XG. Characterisation of welded joints produced by FSW in AA 1100-B4C metal matrix composites. Science and Technology of Welding and Joining. 2012; 17:85–91.

Periyasamy P, Mohan B, Balasubramanian V. Effect of heat input on mechanical and metallurgical properties of friction stir welded AA6061-10% SiCp MMCs. Journal of Materials Engineering and Performance. 2012; 21:2417–28.

Wang D, Xiao BL, Wang QZ, Ma ZY. Friction stir welding of SiCp/2009Al composite plate. Materials and Design. 2013; 47:243–7.

Kalaiselvan K, Dinaharan I, Murugan, N. Characterization of friction stir welded boron carbide particulate reinforced AA6061 aluminum alloy stir cast composite. Materials & Design. 2014; 55:176-182.

Hasan MM., Ishak M, Rejab MRM. A simplified design of clamping system and fixtures for friction stir welding of aluminium alloys. Journal of Mechanical Engineering and Sciences. 2015; 9:1628-1639.

Vijay SJ, Murugan N. Influence of tool pin profile on the metallurgical and mechanical properties of friction stir welded Al–10wt.% TiB 2 metal matrix composite. Materials & Design. 2010; 31(7): 3585-3589.

Wang D, Xiao BL, Wang QZ, Ma ZY. Evolution of the microstructure and strength in the nugget zone of friction stir welded SiCp/Al–Cu–Mg composite. Journal of Materials Science & Technology. 2014; 30(1): 54-60.

Bahrami M, Helmi N, Dehghani K, Givi MKB. Exploring the effects of SiC reinforcement incorporation on mechanical properties of friction stir welded 7075 aluminum alloy: fatigue life, impact energy, tensile strength. Materials Science and Engineering: A. 2014; 595: 173-178.

Minak G, Ceschini L, Boromei I, Ponte M. Fatigue properties of friction stir welded particulate reinforced aluminium matrix composites. nternational Journal of Fatigue. 2009; 32:218–26.

Prado RA, Murr LE, Shindo DJ, Soto KF. Tool wear in the friction stir welding of aluminium alloy 6061 + 20% Al2O3: a preliminary study. Scripta Materialia. 2001; 45(1):75–80

Brinkmann S, Strombeck AV, Schilling C, Dos Santos JF, Lohwasser D, Kocak M. Mechanical and toughness properties of robotic FSW repair welds in 6061-T6 aluminium alloys. GKSS Forschungszentrum Geesthacht Gmbh-Publications-E. 2000; 1(41), All-All.

Grant GJ, Herling DR, Davies RW. Friction stir welding and processing of aluminium metal matrix composites. In: Proceedings. TMS fall meet. USA. 2001: 177–89.

Baxter SC, Reynolds AP. Characterisation of reinforcing particle size distribution in a friction stir welded Al–SiC extrusion. In: Proceedings ann. TMS meet. New Orleans, USA. 2001; 284–93.

Kumar A, Mahapatra MM, Jha PK, Mandal NR, Devuri V. Influence of tool geometries and process variables on friction stir butt welding of Al–4.5% Cu/TiC in situ metal matrix composites. Materials & Design. 2014; 59:406-414.

Karthikeyan L, Senthilkumar VS, Padmanabhan KA. On the role of process variables in the friction stir processing of cast aluminum A319 alloy. Materials & Design. 2010; 31.2: 761-771.

Lima EBF, et al. Dependence of the microstructure, residual stresses and texture of AA 6013 friction stir welds on the welding process. Zeitschrift für Metallkunde. 2003; 94.8: 908-915.

Azimzadega T, Serajzadeh S. An investigation into microstructures and mechanical properties of AA7075-T6 during friction stir welding at relatively high rotational speeds. Journal of materials engineering and performance. 2010; 19.9: 1256-1263.

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Published

2018-12-27

How to Cite

[1]
N. Kaushik, S. Singhal, R. Rajesh, P. Gahlot, and B. N. Tripathi, “Experimental investigations of friction stir welded AA6063 aluminum matrix composite”, J. Mech. Eng. Sci., vol. 12, no. 4, pp. 4127–4140, Dec. 2018.

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