Effect of Heat Input on AA5052 Friction Stir Welds Characteristics

Abstract

Friction Stir Welding (FSW) is a relatively novel solid state welding process that strong enhanced the welding of aluminum alloys for structural applications. In this process, the heat necessary for the required plastic flow of material is produced at the interfase tool-work piece, being affected by factors such as rotational speed, axial load and tool shoulder diameter, among others. The objective of this work was to study the effect of tool shoulder diameter on heat input during FSW of AA5052-H32 alloy and the resulting characteristics of the produced welded joints. Tools of 10, 12, 14 and 16mm shoulder diameter were constructed and used to butt weld plates of 3mm thick of AA5052-H32 aluminum alloy. Welds were made with 514rpm of rotational speed and 98mm/min of welding speed. Thermal cycles were acquired during welding using thermocouples. Macrostructural characterization and Vickers microhardness profiles were done on each welded sample. It was observed an increase in power with shoulder diameter, as well as a lower level of defects in the stirred zone, related with an improved plastic flow. Hardness also decreased with tool diameter, due to a higher thermal effect on the microstructure.