Abstract
The effect of impurities on the electrical conductivity of aluminum has been studied in detail. The electrical conductivity of aluminum is 65.45% of that of copper. The tensile strength of aluminum wire is 150–170 MPa which, at equal conductivity, is about 65% of the strength of copper wire. This strength of aluminum wire is sufficient for bearing the wire’s own weight but may be too low in case of snow, ice or wind overloads. One way to improve the strength of aluminum wire is to use aluminum alloys having higher strength combined with sufficiently high electrical conductivity, e.g. the E-AlMgSi alloy (Aldrey). The key strengthening agent of the E-AlMgSi alloy (Aldrey) is the Mg2Si phase which imparts high mechanical strength to aluminum. In this work we present experimental data on the kinetics of high-temperature oxidation and electrochemical corrosion of indium doped E-AlMgSi aluminum conductor alloy (Aldrey). Thermal gravimetric study has shown that indium doping and high temperature exposure increase the oxidation rate of E-AlMgSi alloy (Aldrey), with the apparent alloy oxidation activation energy decreasing from 120.5 to 91.8 kJ/mole. Alloy oxidation rate data determined using a potentiostatic technique in NaCl electrolyte media have shown that the corrosion resistance of the indium doped alloy is 20–30% superior to that of the initial alloy. With an increase in NaCl electrolyte concentration the electrochemical potentials of the alloys decrease whereas the corrosion rate increases regardless of alloy composition.
Highlights
The main requirements to conductor aluminum alloys are high electrical conductivity, mechanical strength, atmospheric corrosion resistance and susceptibility to pressure mechanical treatment, primarily hot or cold rolling and drawing [1, 2].The main parameters of conductors are the electrical resistivity and its thermal coefficient
The aim of this work is to study the effect of indium doping on the high temperature corrosion and electrochemical corrosion of the E-AlMgSi aluminum conductor alloy (Aldrey)
Indium doping and high temperature exposure increase the oxidation rate of the initial alloy in the solid state which is confirmed by a decrease in the apparent oxidation energy of the E-AlMgSi alloy (Aldrey) from 128.5 to 91.8 for the alloy containing 1 wt.% indium
Summary
The main requirements to conductor aluminum alloys are high electrical conductivity, mechanical strength, atmospheric corrosion resistance and susceptibility to pressure mechanical treatment, primarily hot or cold rolling and drawing [1, 2]. A drawback of aluminum as a conductor is its low mechanical strength For this reason pure aluminum is often replaced for its alloy E-AlMgSi (Aldrey) having the composition Al + 0.5 wt.% Mg + 0.5 wt.% Si. The magnesium to silicon ratio in the alloy should correspond to the composition of the Mg2Si phase which forms in the alloy and acts as a strengthening agent imparting high mechanical strength to the alloy [4]. The aim of this work is to study the effect of indium doping on the high temperature corrosion (oxidation) and electrochemical corrosion of the E-AlMgSi aluminum conductor alloy (Aldrey)
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