钙掺杂对E-AlMgSi (Aldrey)导电铝合金在NaCl电解质介质中阳极行为的影响

Izatullo N. Ganiev, Jamshed H. Jayloev, Ermakhmad J. Kholov, Nargis I. Ganieva
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摘要

为在恶劣条件下使用而设计的新材料面临着使材料耐腐蚀的任务。这项任务的实际解决方案与金属和合金的防腐知识有关。使用导电铝合金制造细导线可能会遇到特殊的问题。这是由于这些合金的强度不足和断裂前的少量扭结造成的。铝合金是近年来发展起来的,即使在软状态下也具有强度特性,使其可以用作导电材料。E-AlMgSi (Aldrey)铝合金是一种著名的导电合金。该合金为热强化合金,塑性好,强度高。经过适当的热处理,该合金获得高导电性。由这种合金制成的电线几乎专门用于空气传输线。本文研究了含钙E-AlMgSi (Aldrey)铝导电合金在0.03、0.3和3.0% NaCl电解质介质中的腐蚀行为。采用PI-50-1.1恒电位仪在2 mV/s电位扫描速率下研究了该合金的阳极行为。钙掺杂E-AlMgSi (Aldrey)铝合金的耐腐蚀性提高了15-20%。掺钙合金的腐蚀电位、点蚀电位和再钝化电位向正区移动。氯化钠电解质浓度的增加导致这些电位的降低。
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Effect of calcium doping on the anodic behavior of E-AlMgSi (Aldrey) conducting aluminum alloy in NaCl electrolyte medium
The design of new materials intended for operation under severe conditions faces the task of rendering the materials corrosion resistant. The practical solution of this task is interrelated with the knowledge of corrosion protection of metals and alloys. The use of conducting aluminum alloys for the manufacture of thin wire may encounter specific problems. This is caused by the insufficient strength of these alloys and a small number of kinks before fracture. Aluminum alloys have been developed in recent years which even in a soft state have strength characteristics that allow them to be used as a conductive material. The E-AlMgSi (Aldrey) aluminum alloy is a well-known conducting alloy. This alloy is a heat-strengthened one, possessing good plasticity and high strength. After appropriate heat treatment this alloy acquires high electrical conductivity. Wires made from this alloy are almost exclusively used for air transmission lines. This work presents data on the corrosion behavior of calcium containing E-AlMgSi (Aldrey) aluminum conducting alloy in 0.03, 0.3 and 3.0% NaCl electrolyte medium. The anodic behavior of the alloy has been studied using a potentiostatic technique with a PI-50-1.1 potentiostat at a 2 mV/s potential sweep rate. Calcium doping of the E-AlMgSi (Aldrey) aluminum alloy increases its corrosion resistance by 15–20%. The corrosion, pitting and repassivation potentials of calcium doped alloys shift toward the positive region. An increase in the sodium chloride electrolyte concentration leads to a decrease in these potentials.
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