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Numerical simulation of friction stir lap welding of Al-to-Mg alloys under different lap configurations and pin lengths

Ming Zhai, Chuansong Wu, Lei Shi

2022Journal of Materials Research and Technology28 citationsDOIOpen Access PDF

Abstract

The lap configurations and pin lengths have important influences on the joint quality and performance in Al-to-Mg friction stir lap welding (FSLW). But how these two factors affect the thermo-mechanical process in Al-to-Mg FSLW remains unclear. In this study, a computational fluid dynamics model considering the effects of local liquation, tool adhesive layer, tool tilt angle and pin thread is developed to analyze the FSLW process of Al-to-Mg with sheet thickness 3 plus 3 mm. The numerical simulation results are experimentally verified by the measured interface temperature and thermal mechanical affected zone profile. For pin length 3.8 mm, the Al/Mg configuration results in higher temperature and stronger material flow, so that intermetallic compounds (IMCs) are easy to form and joint strength is poor. The Al–Mg mixed region in Mg/Al configuration is mainly from the pin bottom to the lap interface, while that in Al/Mg configuration extends from the pin bottom to the position close to the top surface on the advancing side. In Mg/Al configuration, when the pin length increases, the peak temperature increases, the high-temperature region around the tool obviously expands and the tool can drive more materials to flow, which results in a larger Al–Mg mixed region, and the IMCs are more likely to be generated.

Topics & Concepts

Materials scienceFriction stir weldingIntermetallicWeldingLap jointMaterial flowComposite materialMetallurgyAlloyEcologyBiologyAdvanced Welding Techniques AnalysisAluminum Alloys Composites PropertiesAluminum Alloy Microstructure Properties
Numerical simulation of friction stir lap welding of Al-to-Mg alloys under different lap configurations and pin lengths | Litcius