Thermally stable Al conductor prepared from Al powder with a low oxygen content

The high thermal stability of pure Al conductors is an urgent requirement for their applications in power transmission lines. Powder metallurgy (PM) Al conductor was produced in this work from Al powder with a low oxygen content (similar to 0.1 wt%), followed by cold isostatic pressing, sintering, hot extrusion, and cold drawing. The microstructure evolution, mechanical properties and electrical conductivity of hot-extruded rods and cold-drawn wires before and after annealing at 300 degrees C and 500 degrees C were investigated. The gamma-Al2O3 nanoparticles located primarily at high angle grain boundaries promote the stabilization of Al grains, resulting in enhanced annealing strength (89 MPa), almost twice higher than commercial pure Al (45 MPa). Fine grains and texture play a significant role in the overall strength (160 MPa) of PM Al conductors. One interesting finding is that the electrical conductivity of cold-drawn wires (60.2% IACS) is higher than the hot-extruded rods (58.7% IACS) due to the beneficial evolution of initial Al2O3 film and grain boundaries. The compatibility of documented strength-structure Hall-Petch relation was discussed. Optimal properties (172 MPa ultimate tensile strength and 60.2% IACS electrical conductivity) were obtained through cold drawing. These results push forward the potential application of PM Al in heat resistant conductors.

Automated summary

High thermal stability of pure Al conductors is crucial for their applications in power transmission lines. By utilizing powder metallurgy and optimizing the processing, this study was able to enhance the strength and electrical conductivity of Al conductors. The cold-drawn wires exhibited higher electrical conductivity and optimal mechanical properties, pushing forward the potential application of PM Al in heat resistant conductors.