Metallurgical characteristics of AA6061 aluminium and AZ31B magnesium dissimilar joints by fusion welding technique

Abstract

AbstractAluminium (Al) and magnesium (Mg) alloys are extensively used in the automobile sector because of their high strength‐to‐weight ratio, excellent castability low density and simplicity of recycling. Al‐Mg structures used in the automotive sector can potentially reduce their weight. Although there is a significant opportunity for substantial cost reduction, the use of magnesium in aluminium structures remains restricted. This study aims to weld 3 mm‐thick rolled sheets of AA6061 Al and AZ31B Mg alloy using the cold metal transfer (CMT) arc welding process. Three different filler wires (ER1100, ER4043, and ER5356) were used in the experiment. In this article, the mechanical and microstructure characteristics of Al/Mg dissimilar joints manufactured by CMT are evaluated and discussed in detail. Optical microscope (OM), scanning electron microscopy (SEM), energy dispersive x‐ray spectroscopy (EDX), and x‐ray diffraction (XRD) were used to analyze the CMT‐welded Al/Mg dissimilar joints. Of the three filler wires used, ER4043 (Al‐5%Si) filler wire yielded defect‐free sound joints due to the presence of Si, which improves the flow ability of molten filler during welding. The presence of Mg‐rich intermetallics‐Al12Mg17) and Al‐rich intermetallics‐Al3Mg2 were observed. The fractured area of the CMT‐welded Al/Mg dissimilar joints revealed the presence of the Mg‐rich intermetallics (Al12Mg17), which is responsible for the decrease in tensile strength. The reduction of intermetallics, particularly of Mg‐rich intermetallics (Al12Mg17) is important for improving joint strength.Research Highlights Cold metal transfer (CMT) arc welding was used to control the Al‐Mg‐rich intermetallics in the Al/Mg dissimilar joints. The microstructure, morphology and phase composition of the welded joints were studied by OM, SEM, TEM, EDS and XRD. The weld metal and AL substrate bonded with a strong interface, while weld metal and Mg substrate were joined at the epitaxial solidification area where the intermetallic compounds of Mg2Al3, Mg17Al12 and Mg2Si are generated. The weld metal on the Mg side experienced brittle fracture, with a continuous distribution of Mg2Al3, Mg17Al12 and Mg2Si.