EFFECT OF VOLTAGE ON THE THICKNESS OF OXIDE LAYER AT ALUMINUM ALLOYS FOR STRUCTURAL BONDING USING PHOSPHORIC SULFURIC ACID ANODIZING (PSA) PROCESS

International Journal of Mechanical Engineering Technologies and Applications Pub Date : 2023-01-31 DOI:10.21776/mechta.2023.004.01.8

H. N. Chamidy, A. Ngatin, Anisa Fitriani Rosyadi, Arisya Julviana, Noviyani Noviyani

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引用次数: 2

Abstract

The aerospace industry mostly uses the aluminum alloys 2xxx and 7xxx series for their fuselage construction, and some of them are assembled using structural bonding because it is strong, easy during the fabrication process, resistant to corrosion, and non-toxic. The anodization process is a proven surface treatment method for structural bonding. Phosphoric Sulfuric Acid Anodizing (PSA) is an eco-friendly alternative as a chromate-free solvent technology for the anodizing process that is applied for structural bonding. The thickness of the oxide layer caused by the voltage given in this process was evaluated in terms of corrosion resistance using the oxide layer's thickness as the main factor. The PSA process of AA2024 T3 clad was carried out at a constant concentration of 125 g/L of phosphoric acid, 80 g/L of sulfuric acid, 27 A, and a temperature of 26 to 28 OC for 23 minutes with various voltages. The voltage was varied at 16, 18, and 20 VDC. The optimum condition for the voltage applied was 18 VDC, which resulted in an oxide layer thickness of 2.76 µm.

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电压对磷酸硫酸阳极氧化(psa)铝合金结构键合氧化层厚度的影响

航空航天工业主要使用铝合金2xxx和7xxx系列的机身结构，其中一些是使用结构粘接组装，因为它是坚固的，在制造过程中容易，耐腐蚀，无毒。阳极氧化工艺是一种成熟的结构键合表面处理方法。磷酸硫酸阳极氧化(PSA)是一种环保型的无铬溶剂阳极氧化技术，可用于结构键合。以氧化层厚度为主要因素，评价了该工艺中给定电压引起的氧化层厚度的耐蚀性。在恒定浓度为125 g/L的磷酸、80 g/L的硫酸、27 a、26 ~ 28 OC、不同电压条件下，对AA2024 T3包层进行PSA过程，持续23 min。电压在16、18和20 VDC变化。当电压为18 VDC时，氧化层厚度为2.76µm。

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International Journal of Mechanical Engineering Technologies and Applications

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