Abstract
Thermal cycles and deformations during high-speed micro friction stir welding (μFSW) under different welding conditions were studied by experimental methods. The results show that the peak temperature and elevated-temperature exposure time (t150) increased with the increasing of rotational speed and decreased with the increasing of welding speed. Increasing rotational speed or welding speed led to an increase in both heating and cooling rates. The joint fabricated by the pinless tool experienced a lower peak temperature, a shorter elevated-temperature exposure time, and a larger temperature gradient than that by the pin tool. The welded sheet presented an anti-saddle deformation character, with convex bending in a longitudinal direction and concave angular bending in a transverse direction. In comparison to the pin tool, the longitudinal maximum bending deformation, Zmax, of the joint fabricated by the pinless tool was reduced by 12.35%, and the transverse angular deformation, α, was reduced by 6.67%. In comparison to the steel backing plate, the Zmax of the joint produced using a copper backing plate was reduced by 40.66%, but the α was increased by 53.27%.
Highlights
IntroductionZhang et al [3] conducted high-speed Friction stir welding (FSW) experiments on an AA7075-T6 sheet, reporting that the higher welding speed resulted in narrower, stronger heat-affected zones (HAZs) and higher hardness in the nugget zones (NZs)
Friction stir welding (FSW) technology is considered to be one of the most important advancements in industrial manufacturing due to its energy efficiency, environment friendliness, and versatility [1,2].Zhang et al [3] conducted high-speed FSW experiments on an AA7075-T6 sheet, reporting that the higher welding speed resulted in narrower, stronger heat-affected zones (HAZs) and higher hardness in the nugget zones (NZs)
In comparison to the pin tool, the Zmax and α of the joint fabricated by the pinless tool were reduced by 12.35% and
Summary
Zhang et al [3] conducted high-speed FSW experiments on an AA7075-T6 sheet, reporting that the higher welding speed resulted in narrower, stronger heat-affected zones (HAZs) and higher hardness in the nugget zones (NZs). Zhang et al [4] studied the microstructure and corrosion properties of high-speed FSW of AA7075 sheets. Azimzadegan et al [5] investigated the microstructures and mechanical properties of AA7075-T6 during FSW at relatively high rotational speeds. The thermal cycles during FSW play a crucial role in the deformation. Research on the thermal cycles of FSW has mainly focused on medium and thick plates [7,8,9]. There is little research on the thermal cycles for FSW of ultrathin sheets
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