Abstract
The aim of this research is to investigate the sequence of processes for improving the welded surface integrity of AA7075-T651 aluminum alloy joined by friction stir welding (FSW). The improvement processes that will be investigated herein include mechanical surface improvement with deep rolling (DR) and post-weld heat treatment (PWHT). Therefore, this study investigated welded surface integrity, which comprises residual stress, microhardness, surface roughness, microstructure, and fatigue life (screening). The experiment consists of three sets of combinations. In the first set, only FSW was applied; in the second set, FSW was applied, followed by DR, and then PWHT processes (FSW-DR-PWHT); and in the last set, FSW was applied, followed by PWHT, and then DR processes (FSW-PWHT-DR). Fatigue testing was carried out by undertaking a four-point bending test using a bending stress of approximately 300 MPa with a test frequency of 2.5 Hz at room temperature and stress ratio R = 0. The study found that residual stress plays an important role in the fatigue life. Finally, the fatigue test showed that FSW workpieces subject to the PWHT process followed by the DR process (FSW-PWHT-DR) had the highest fatigue life, with an increase of 239% when compared with unprocessed FSW workpieces.
Highlights
Friction stir welding (FSW) is a popular aluminum welding process that can be used to weld dissimilar materials
The FSW workpiece, when subject to the welding conditions investigated in this research, was found to be satisfactory according to the compressive residual stress results
Investigation of the sequence of deep rolling (DR) and post-weld heat treatment (PWHT) processes to improve the welded surface integrity of FSW, FSW-DR-PWHT, and FSW-PWHT-DR workpieces on AA7075-T651 aluminum alloy led to the following conclusions: 1
Summary
Friction stir welding (FSW) is a popular aluminum welding process that can be used to weld dissimilar materials It was invented in 1991 in the United Kingdom by The Welding Institute (TWI). The FSW process involves several welding parameters, including rotational speed, feed rate, tilt angle, penetration depth, characteristics of the welding tool used (pin length, pin characteristics, shoulder diameter, and shoulder shape), material properties, cooling system, clamping system, etc. These factors affect the quality of the weld and must be controlled if the materials involved are to be properly welded [2,3,4]. In the case of low-cycle fatigue with a high-stress level, the fracture area
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