Fig. 4 Time-temperature curves at 95% maximum strength for 6061-T6 and 6069-T6. (a) Yield strength. (b) Ultimate tensile strength. Copyright © 2011 M.E. Kassner et al. This is an open-access article distributed under the Creative Commons. Source: Ref 7 More

Fig. 51 Time-temperature-property curve for 95% maximum yield strength of 6061-T6 and 6069-T6. Source: Ref 174 More

Fig. 2 Range in amount of reinforcement. (a) SiC P /6061-T6 Al metal-matrix composite (MMC) with 15 vol% reinforcement. (b) Si P /Al MMC with 43 vol% reinforcement More

Fig. 3 Anodic polarization diagrams of Ti-15-3 ( Ref 14 , 15 ) and 6061-T6 Al ( Ref 16 ) in deaerated 3.15 wt% NaCl at 30 °C (86 °F). Cathodic polarization diagram of P100 Gr fibers ( Ref 16 ) in aerated 3.15 wt% NaCl at 30 °C (86 °F). Scan rate, 0.1 mV/s. E , potential; SCE, standard More

Fig. 14 Anodic polarization diagrams of P100 Gr, monolithic 6061-T6 Al, and an actual P100 Gr (50 vol% fiber)/6061-T6 Al metal-matrix composite (MMC) exposed to deaerated 0.5 M Na 2 SO 4 at 30 °C (86 °F); scan rate, 0.1 mV/s ( Ref 55 ). The discrepancy between the polarization diagram More

Fig. 42 Effect of quenching medium on strength of 6061-T6 sheet. Water-immersion quench equals 100%. Control of coolant flow will minimize the decrease in mechanical properties. 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. 10 Forged and formed aluminum alloy 6061-T6 truck wheels More

Fig. 4 Hexagonal nut for which a change from alloy 6061-T6 to 6262-T9 resulted in a savings of material and less burring of the tapped thread. Dimensions given in inches More

Fig. 2 Slow potentiodynamic scans of aluminum 6061-T6 in 3.5% NaCl with and without volatile corrosion inhibitor F. Source: Ref 39 . More

Fig. 6 Example of a 6061-T6 32 mm (1.25 in.) diameter, 1 mm (0.04 in.) wall thickness tube electromagnetically crimped onto four nuts using four electromagnetic discharges and a coil similar to that shown in Fig. 5(a) . The nuts are tight after forming and after destructive testing. More

Fig. 1 Stress-strain curves for alloy 6061-T6 drawn tube. (a) Complete tensile curve, 200 mm (8 in.) gage length. (b) Expanded tensile curve, 200 mm (8 in.) gage length. (c) Compressive curve. (d) Shear curve. YS, yield strength More

Fig. 24 Rotating-beam fatigue band for alloy 6061-T6 products in the longitudinal, long-transverse, and short-transverse directions More

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

Fig. 1 Time-temperature-property curve for 95% maximum yield strength of 6061-T6 and 6069-T6. The greater quench sensitivity of 6069 is associated with the increased amount of magnesium, silicon, manganese, and chromium, which increase the nucleation rate and Mg 2 Si concentration. Source More

Fig. 4 Time-temperature-property curve for 95% maximum yield strength of 6061-T6 and 6069-T6. Source: Ref 5 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. 10 Two views of various thicknesses of 6061-T6 aluminum used in piercing studies with varying water pressure and garnet flow rates used on each thickness. (a) Three-dimensional view of workpiece showing varying thickness of 640 mm (2 ft) long slab before piercing. From left to right, slab More

Fig. 10 Hardness profiles of the HAZ of gas-tungsten arc welds on 6061-T6 using various heat inputs. Source: Ref 39 More

Fig. 6 Hexagonal nut for which a change from alloy AA 6061-T6 to AA 6262-T9 resulted in a cost-savings. Dimensions given in inches More