Transactions of Materials and Heat Treatment

Title：Microstructure heredity and corrosion resistance of 3XXX series aluminum alloy

Authors： Ma Fang1 Guo Fengjia2 Zhang Qian1 Sun Ning2 Wang Jingtao2

Unit： 1. College of Chemical Engineering and Technology Yantai Nanshan University 2. National Engineering Research Center for Plastic Working of Aluminium Alloys Shandong Nanshan Aluminium Co. Ltd.

KeyWords： 3XXX series aluminum alloy corrosion Fe-containing phase phase transition microstructure

ClassificationCode：TG146.2

year,vol(issue):pagenumber：2024,49(11):217-225

Abstract：

The microstructure of 3XXX series aluminum alloy ingots, the transformation of the second phases such as Fe-containing phase during homogenization process and the morphological changes of finished material can samples during the boiling process by disinfectants were studied by means of metallographic microscope, scanning electron microscope and matching energy spectrometer. The results show that during different production processes such as alloy melting, homogenization and rolling deformation, the microstructure of 3XXX aluminum alloy can be corroded under specific conditions, and the content and morphology of Fe-containing phase in the microstructure can be affected by the external corrosion environment to varying degrees. The Al6(Fe, Mn) phase, which is larger in size and exists in a sharp state, scratches the matrix structure during the rolling deformation process, promoting the matrix corrosion. The α-Al12(Fe, Mn)3Si phase, which is relatively distributed in a discontinuous and round shape, has higher corrosion resistance and can improve the processing performance of the alloy structure. After boiling by disinfectants, the finished material samples mainly exhibit corrosion characteristics at the defect damage areas of the aluminum matrix, and the degree of corrosion increases with the increasing of the damage degree of matrix tissue.

Funds：

烟台市科技计划（2022XDRH035）；龙口市科技计划（2020KJJH006）

作者简介：麻芳(1982-），女，硕士，讲师 E-mail：mafang@nanshan.edu.cn 通信作者：孙宁(1995-)，女，硕士，工程师 E-mail：ningsun95@163.com

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