Pitting Corrosion of Natural Aged Al⁻Mg⁻Si Extrusion Profile.

Quanmei Guan,Jianying Hou,Jijun Ma,Bin Tang,Haisheng Wang,Hongchao Kou,Jun Gao,William Wang,Jing Sun,Chengxiong Zou,Junfeng Gao,Jun Wang,Jinshan Li

doi:10.3390/ma12071081

Quanmei Guan, Jianying Hou + Show 11 more

Open Access

PDF Available

https://doi.org/10.3390/ma12071081

Copy DOI

Export

Save

Cite

Abstract
Highlights/Summary
Full-Text PDF
Similar Papers

Abstract

Listen

With the quick development of the high-speed railway and the service of the China Railway High-speed (CRH) series for almost a decade, one of the greatest challenges is the management/maintenance of these trains in environmental conditions. It is critical to estimate pitting damage initiation and accumulation and set up a corresponding database in order to support the foundations for interactive corrosion risk management. In this work, the pitting corrosion of a nature-aged commercial 6005A-T6 aluminum extrusion profile for 200 days was studied comprehensively. The heterogeneous microstructures were conventionally identified by the in situ eddy current, suggesting which investigated regions to fabricate samples for. After constant immersion for 240 h in 3.5 wt % NaCl, the shapes and depths of the pits were captured and measured by optical microscope (OM) and three-dimensional optical profilometry (OP), providing detailed quantification of uniform pitting corrosion. The typical features of the pits dominated by the distribution of precipitates include the peripheral dissolution of the Al matrix, channeling corrosion, intergranular attack, and large pits in the grains. Due to the high density of continuous anodic and cathodic particles constituted by alloying elements in coarse grains, the number of pits in the coarse grains was the highest while the number in the fine grains was the lowest, indicating that fine grains have the best corrosion resistance. The experimental dataset of the pit depth integrated with its corresponding microstructure would set the benchmark for further modeling of the pit depth and the remaining ductility, in order to manage the damage tolerance of the materials.

Highlights

Age hardenable Al-Mg-Si (6XXX) alloys are widely utilized in the aerospace, transport, automotive, and shipbuilding industries due to their high strength-to-weight ratio, recyclability, and resistance to corrosion [1,2,3]
Based on the initial rough shows the linear plot of the microstructures eddy current of along the naturally aged 6005A-T6 alloy
BasedOn on the measurements, it contour was found that the x-direction were homogeneous

Summary

Introduction

Age hardenable Al-Mg-Si (6XXX) alloys are widely utilized in the aerospace, transport, automotive, and shipbuilding industries due to their high strength-to-weight ratio, recyclability, and resistance to corrosion [1,2,3]. They get further preference for industrial application than other series, such as Al-Cu-based (2XXX) and Al-Zn-based (7XXX) alloys, due to the lower amount of alloying element that they have and, their lower cost [4]. The precipitation sequence of Al-Mg-Si alloys has been reported as [3,5,6,7,8]: SSSS → solute clusters → GP Zones → β”→ β0. The L phase is believed to be a Q0 precursor, playing an important effect in strengthening the alloy [7]

Methods

Results

Conclusion