Reverse effects of pre-deformation and traverse speed on the mechanical properties of friction stir processed pure copper

Abstract

In the present work, the effects of pre-strain and traverse speed on the microstructural evolution and tensile behavior of friction stir processed (FSPed) pure copper were investigated. In the samples without pre-deformation (0% samples), with the increment of the traverse speed from 100 mm min−1 to 200 mm min−1, the grain size decreased from 5.2 to 2.5 μm due to heat input domination. In the 60% pre-rolled samples (60% samples), interestingly, with an increase in the traverse speed (from 100 mm min−1 to 200 mm min−1), the average grain size increased from 2.4 to 6.8 μm owing to the domination of deformation degree. With the increment of speed from 100 mm min−1 to 200 mm min−1 in the 0% samples, the YS and UTS increased from 158.6 and 244.6 MPa to 190.7 and 253.9 MPa, respectively, due to decrement in the mean grain size. In addition, the increment of speed from 100 mm min−1 to 200 mm min−1 in the 60% samples reduced the YS and UTS from 177.9 and 261.7 MPa to 138.9 and 234.8 MPa, respectively, due to the increase in the mean grain size. In the 0% FSPed copper, by increasing the speed, the depth and size of dimples reduced, while, in the 60% FSPed samples, when the traverse speed increased, the dimples became larger.