Abstract
AbstractIn this work, thin aluminum alloy sheets with thickness of 0.8 mm were friction stir lap welded using small shoulder plunge depths of 0 and 0.1 mm. The joint formation, microstructure and mechanical properties were investigated. Results show that voids appear inside the stir zone when the small plunge depth of 0 mm is used because the tool shoulder cannot exert a good material-collecting effect at such low plunge depth. A plunge depth of 0.1 mm causes tight contact between the shoulder and the material and thus results in good material-collecting effect, which is helpful to eliminate the void. Sound joints are attained at a wide range of welding parameters when using the shoulder plunge depth of 0.1 mm. No crack is observed inside the bonding ligament. The joints own higher failure loads when the retreating side (RS) of the joint bares the main load during the lap shear tests. The shear failure load first increases and then decreases with increasing the rotating and welding speeds, and the maximum failure load of 6419 N is obtained at 600 rpm and 150 mm/min. The hardness of the joint presents a “W” morphology and the minimum hardness is obtained at the heat affected zone. The joints present tensile fracture and shear fracture when the advancing side and RS bare the main loads, respectively.
Highlights
In this work, thin aluminum alloy sheets with thickness of 0.8 mm were friction stir lap welded using small shoulder plunge depths of 0 and 0.1 mm
The 2024-T4 Al alloys of 0.8 mm thick were chosen as the base metal (BM)
Lap shear tests were performed on an Instron 8801 testing machine at a speed of 3 mm/min under room temperature
Summary
Abstract: In this work, thin aluminum alloy sheets with thickness of 0.8 mm were friction stir lap welded using small shoulder plunge depths of 0 and 0.1 mm. FSW has been widely used to join various kinds of Al alloys and the microstructure and mechanical properties of the welded joints have been studied [12,13,14,15,16,17]. Martinez et al [21] studied the microstructure and mechanical properties of thick 7449 Al alloy FSW joint and found that the joint bottom had higher hardness compared to that of the BM. Different sleeve plunge depths were used, and the microstructure and mechanical properties of the lap joints were studied
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