Oxygen Availability and Corrosion Propagation in RC Structures in the Marine Environment—Inferences from Field and Laboratory Studies

A. Moore, H. Beushausen, M. Otieno, Joanitta Ndawula, M. Alexander
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引用次数: 1

Abstract

The splash and spray and tidal zones are generally assumed to be the most severe marine exposure environments with respect to steel reinforcement corrosion in concrete structures. However, it has been observed in several aged marine structures along the Southern African coastlines, that there is usually relatively insignificant reinforcement corrosion damage in the tidal zone, despite very high (above-threshold) chloride contents. To develop a full understanding of the severity of marine exposure conditions with regard to the actual deterioration, it is imperative that other factors that directly affect corrosion, such as oxygen availability at the steel surface (which is influenced by concrete quality, cover thickness and moisture condition), are carefully considered. The laboratory experimental work in the study presented in this paper comprised of different cover depths (10, 20 and 30 mm) and w/b ratios (0.5 and 0.8) and simulated marine tidal, splash and submerged environments. The results show that for any give exposure environment, the relative influence of each of the various factors considered should be considered in conjunction with the other factors; this finding can be generalized to include all relevant factors that can affect corrosion in a given exposure environment including ambient temperature. For example, a cover depth of 30 mm in the tidal zone with a simulated intertidal duration of 6 h effectively resulted in similar corrosion behavior to that in the submerged zone. The paper concludes that engineers should consider these factors when applying standard exposure classes in the design for durability of marine structures.
海洋环境中钢筋混凝土结构的氧可用性和腐蚀扩展——来自现场和实验室研究的推论
飞溅、浪花和潮汐带通常被认为是混凝土结构中钢筋腐蚀最严重的海洋暴露环境。然而,在沿南部非洲海岸线的几个古老的海洋结构中观察到,尽管氯化物含量非常高(高于阈值),但潮带的钢筋腐蚀损害通常相对较小。为了充分了解海洋暴露条件对实际恶化的严重程度,必须仔细考虑其他直接影响腐蚀的因素,例如钢表面的氧气可用性(受混凝土质量,覆盖厚度和湿度条件的影响)。本文的实验室实验工作包括不同的覆盖深度(10、20和30 mm)和w/b比(0.5和0.8),并模拟了海洋潮汐、飞溅和淹没环境。结果表明,对于任何给定的暴露环境,每一种因素的相对影响都应与其他因素结合考虑;这一发现可以推广到包括在给定的暴露环境(包括环境温度)中可能影响腐蚀的所有相关因素。例如,潮汐区覆盖深度为30 mm,模拟潮间带持续时间为6 h,有效地导致了与淹没区相似的腐蚀行为。本文的结论是,工程师在采用标准暴露等级进行海洋结构耐久性设计时应考虑这些因素。
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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