V. Subbotina, Oleg Sоbоl`, V. Belozerov, Ubeidulla F. Al-Qawabeha, T. Tabaza, Safwan Moh`d Al-Qawabah, V. Shnayder
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引用次数: 2

摘要

研究了不同电解液成分下电解条件对AMg6铝合金微弧氧化涂层相形成及性能的影响。电解采用碱性电解质(蒸馏水中的(KOH)溶液)、硅酸盐电解质(含有不同比例的na2sio3成分)和复合碱性硅酸盐电解质(含液体玻璃(1÷12 g/l na2sio3)和氢氧化钾(1÷6 g/l KOH))。结果表明,电解液类型和微弧氧化工艺条件的选择可以使AMg6铝合金的相结构状态、厚度和性能发生很大的变化。微弧氧化后涂层相结构状态的判定标准是涂层形成过程中γ-Al 2o3→α-Al 2o3转变过程的完备性。由于γ-Al 2o3相的形成和缺乏γ-Al 2o3→α-Al 2o3转变的热力学条件,使用碱性电解质不能获得高硬度的涂层。当使用硅酸盐电解质时,可以显著提高涂层的生长速度,但同时,较大的比Si浓度的存在刺激了莫来石和非晶态相的形成。混合的碱性硅酸盐电解质(含不同比例的KOH+ na2sio3)和低含量(6 g/l)的na2sio3溶液刺激莫来石的形成。这在KOH含量最低(1 g/l)时表现得最为明显。在较高的KOH含量(2g /l)时,碱性电解质的过程特征成为主导。这导致转变反应不完全,只形成γ-Al 2o3相。当电解液中na2sio3比含量达到12 g/l时,实现γ - al2o3→α - al2o3转化的热力学条件成为可能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Study of the Electrolyte Composition Influence on the Structure and Properties of MAO Coatings Formed on AMg6 Alloy
The influence of electrolysis conditions at different electrolyte compositions on the phase formation and properties of coatings obtained by microarc oxidation (MAO) on an aluminum alloy AMg6 was studied. For electrolysis, three types of electrolytes were used: alkaline electrolyte ((KOH) solution in distilled water), silicate electrolyte (with different percentages of Na 2 SiO 3 component) and complex alkaline silicate electrolyte with liquid glass (1÷12 g/l Na 2 SiO 3 ) and potassium hydroxide (1÷6 g/l KOH). An analysis of the results showed that the choice of electrolyte type and conditions of the microarc oxidation process allows a wide variation in the phase-structural state, thickness and properties of the AMg6 aluminum alloy. The criterion for the expected phase-structural state of the coatings as a result of microarc oxidation is the completeness of the γ–Al 2 O 3 →α–Al 2 O 3 transformation process during coating formation. The use of an alkaline electrolyte does not allow achieving a high hardness of the coating due to the formation of the γ-Al 2 O 3 phase and the absence of thermodynamic conditions for the γ–Al 2 O 3 →α–Al 2 O 3 transition. When using a silicate electrolyte, it is possible to significantly increase the growth rate of the coating, but at the same time, the presence of a large specific Si concentration stimulates the formation of mullite and an amorphous-like phase. The use of a combined alkaline silicate electrolyte (with different percentages of KOH+Na 2 SiO 3 ) with a low content (6 g/l) of Na 2 SiO 3 in solution stimulates the formation of mullite. This is manifested to the greatest extent with the lowest content (1 g/l) of the KOH component. At a higher content (2 g/l) of the KOH component, the processes characteristic of an alkaline electrolyte become dominant. This leads to an incomplete transformation reaction and the formation of only the γ-Al 2 O 3 phase. The achievement of the thermodynamic conditions of the γ–Al 2 O 3 →α–Al 2 O 3 conversion became possible with an increase in the specific Na 2 SiO 3 content in the electrolyte solution to 12 g/l. In this case, MAO coatings were formed on the AMg6 alloy with the highest hardness of 1500 kg/mm 2 and high electric strength of 12 V/μm
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