Galvanic Corrosion and Fatigue Behavior of a SM480C Welded Joint Steel in a Sea-Crossing Suspension Bridge

IF 1.5 Q4 ELECTROCHEMISTRY

International Journal of Corrosion Pub Date : 2022-07-29 DOI:10.1155/2022/2665663

Xudong Zhou, Xinmin Zhang, Ruiwen Xu, Bin Li, X. Ren, Jinyang Zhu, Ying Jin

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Abstract

The corrosion tendency and fatigue behavior of a SM480C welded joint in a sea-crossing suspension bridge after twenty-year exposure to a marine environment was investigated in this work. It was found that the corrosion product on the whole surface of the welded joint is loose, with many holes and cracks, which allowing corrosive media enter and reach the surface of the substrate. Localized corrosion occurred in the weld zone (WZ) and the heat-affected zone (HAZ), the maximum depth of localized corrosion in the HAZ reached 1.8 mm, and the maximum local corrosion rate is 0.082 mm/y. By using Bimetallic Conjugation Theory calculations, the galvanic effect of the welded joint was qualified, indicates that HAZ was the most corrosion susceptible area in the welded joint. The galvanic corrosion current on HAZ reached approximately 2 μA, which is much higher than the corrosion of isolated HAZ by about 6.5 times. The corrosion has an obvious influence on the fatigue performance, the elongation of the bridge deck decreases by 40%~70%, and the tensile strength decreases by 4.5%~31.33%. In order to ensure the service safety and avoid premature failure, the average thickness of the corroded bridge deck should not be less than 10 mm under the stress amplitude of 115 MPa.

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SM480C焊接接头钢在跨海悬索桥中的电腐蚀和疲劳行为

研究了跨海悬索桥SM480C焊接接头在海洋环境中暴露20年后的腐蚀趋势和疲劳行为。研究发现，焊接接头整个表面的腐蚀产物疏松，有许多孔洞和裂纹，使腐蚀介质进入并到达基体表面。焊接区（WZ）和热影响区（HAZ）发生局部腐蚀，HAZ局部腐蚀的最大深度达到1.8 mm，最大局部腐蚀率为0.082 mm/y。通过双金属共轭理论计算，焊接接头的电流效应合格，表明HAZ是焊接接头中最易腐蚀的区域。HAZ上的电流腐蚀电流达到约2 μA，这比隔离HAZ的腐蚀高出约6.5倍。腐蚀对疲劳性能有明显影响，桥面伸长率下降40%～70%，抗拉强度下降4.5%～31.33%。为了保证使用安全，避免过早失效，腐蚀桥面的平均厚度不应小于10 在115的应力振幅下为mm MPa。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Corrosion ELECTROCHEMISTRY-

CiteScore

5.70

自引率

0.00%

发文量

审稿时长

14 weeks