Search Results for aluminum alloy 6061

Fig. 12 Shallow part that was drawn from aluminum alloy 6061-O with a rubber pad and a rigid female steel die, in one operation. Dimensions given in inches More

Fig. 18 Aluminum alloy 6061 instrument container fabricated from a blank by explosive forming. Courtesy of Explosive Fabricators, Inc. More

Fig. 44 (a) Top view of aluminum alloy 6061 disk compressed between dies. (b) Cracks form at the transition region between rough and smooth areas of the die. More

Fig. 4 (a) Rotary-forged aluminum alloy 6061 bearing retainer used in bicycle hubs. (b) Schematics of the rotary forge used to produce the bearing retainer and the workpiece deformation process (left) More

Fig. 10 Forged and formed aluminum alloy 6061-T6 truck wheels More

Fig. 44 Tensile fractures of aluminum alloy (6061-T6) sections with various width-thickness ( w / t ) ratios: (a) Diffuse necking ( w / t = 1). (b) Diffuse necking with w / t = 3.85. (c) Local necking superimposed on a diffuse neck with w / t = 12 with magnified side view 1.5×. Courtesy More

Fig. 5 Logarithmic plot of stress versus rupture life for aluminum alloy 6061-T651 More

Fig. 44 Tensile fractures of aluminum alloy 6061-T6 sections with various width-to-thickness ( w / t ) ratios. (a) Diffuse necking ( w / t = 1). (b) Diffuse necking with w / t = 3.85. (c) Local necking superimposed on a diffuse neck with w / t = 12 with magnified side view 1.5×. Courtesy More

Fig. 34 (a) Top view of aluminum alloy 6061 disk compressed between dies. (b) Cracks form at the transition region between rough and smooth areas of the die. More

Fig. 23 Forged and formed aluminum alloy 6061-T6 truck wheels More

Fig. 31 Aluminum alloy 6061-T6 forged truck wheels with bright anodized finish More

Fig. 4 Micrograph of cast and homogenized 6061 aluminum alloy, showing the precipitate-free zone (PFZ) (lack of Mg 2 Si precipitates) at grain boundary. The PFZ was created by the lack of silicon, which is wrapped up in the AlFeSi precipitates at the grain boundary. Source: Ref 4 More

Fig. 13 Density of 6061-T6 aluminum alloy drawn under different externally applied hydrostatic pressures as a function of thickness. Nominal 27% reduction per pass with die half-angle of 25°. Source: Ref 17 More

Fig. 14 Actual weld microstructures corresponding to schematics of Fig. 13 . (a) Grain structure of a GTAW of aluminum alloy 6061, made with Q of 700 W (200 Btu/h) and V of 5.1 mm/s (0.20 in./s). (b) Grain structure of a GTAW of pure aluminum, made with V of 20.8 mm/s (0.819 in./s). (c More

Fig. 107 Halide-flux inclusion (rounded granules) in the joint between an actuator and an attachment bracket of aluminum alloy 6061 that were joined by dip brazing using an Al-12Si brazing alloy More

Fig. 12 Precipitation heat treatment or artificial aging curves for solution heat-treated aluminum alloy 6061 More

Fig. 19 Precipitation heat treatment or artificial aging curves for solution heat treated aluminum alloy 6061 More

Fig. 9 Precipitation heat treatment or artificial aging curves for solution heat-treated aluminum alloy 6061 More

Fig. 55 Final part shape and FE predicted optimal preform shape for hydroforming of aluminum alloy 6061-T4 tube. Source: Ref 217 More