钢筋混凝土结构腐蚀寿命预测的比较研究

IF 3.5 Q1 ENGINEERING, MULTIDISCIPLINARY
Kuleni Fekadu Yadeta, S. Siriwardane, T. A. Mohammed
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The shortcomings and limitations of the existing models are discussed.FindingsThe empirical models typically depend on the rate of corrosion, diameter of steel reinforcement and concrete cover depth and based on basic mathematical formula. In contrast, the analytical and numerical models contain the strength and stiffness properties of concrete as well as type of corrosion products and incorporate more complex mechanical factors. Four existing analytical models were analyzed and their performance was evaluated against existing experimental data in literature. All the considered analytical models were assumed thick-walled cylinder models. The maximum difference between observed cracking time from different test data and calculated cracking time using the developed models is 36.5%. The cracking times extend with increase in concrete cover and decrease with corrosion current density. 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引用次数: 0

摘要

对腐蚀程度和达到特定安全限值所需时间的可靠估计对于评估老化钢筋混凝土(RC)桥梁的可靠性至关重要。工程师和决策者可以使用这些数字来计划适当的检查和维护操作。设计/方法/方法提出并比较了估算腐蚀钢筋混凝土结构使用寿命的分析方法、经验方法和数值方法。将先前提出的分析模型预测的混凝土覆盖层开裂时间与试验得到的开裂时间进行比较,以确定RC桥梁的模型/s。讨论了现有模型的不足和局限性。经验模型通常取决于腐蚀速率、钢筋直径和混凝土覆盖深度,并基于基本的数学公式。相比之下,分析和数值模型包含混凝土的强度和刚度特性以及腐蚀产物的类型,并包含更复杂的机械因素。分析了现有的四种分析模型,并根据文献中现有的实验数据对其性能进行了评估。所有考虑的分析模型都假定为厚壁圆筒模型。不同试验数据观测到的开裂时间与利用所建立模型计算出的开裂时间最大差异为36.5%。裂缝时间随混凝土覆盖层的增加而延长,随腐蚀电流密度的增大而减小。考虑混凝土非均质性、钢筋非均匀腐蚀、锈蚀率以及更准确地表示腐蚀适应区域等因素的使用寿命预测模型的发展是有待进一步研究的领域。本文的研究结果在一定程度上弥补了理论与实践之间的差距,因为它是评估受腐蚀影响的RC结构的使用能力并提出结构维护和维修策略的基础。裂缝宽度准则在结构设计和评价中具有重要的现实意义,应引起结构工程师、施工人员和资产管理人员的高度重视。此外,由于腐蚀导致的可使用性失效,特别是混凝土开裂和剥落,其修复成本明显高于强度失效。因此,为了优化钢筋混凝土结构的维护成本,对受腐蚀影响的混凝土结构的使用能力进行精确预测是至关重要的。通过及时维修,可以延长钢筋混凝土结构的使用寿命。这有助于利益相关者管理资源。为了改进腐蚀诱发裂纹的建模,确定了未来研究的重要领域。现有模型未考虑混凝土的非均质性、多孔区概念(应量化孔隙的调节作用)、实际腐蚀形态(沿钢筋长度的非均匀腐蚀)、承受荷载与腐蚀之间的相互作用。因此,本工作建议进一步研究应将其作为输入,开发具有最佳预测能力的模型。社会影响这项工作对社会有积极的影响,不会影响生活质量。预测结构的使用寿命是制定维护和维修策略的必要条件。优化维护策略用于延长资产寿命,减少资产故障,最大限度地降低维修成本,并改善社会健康和安全。通过将预测的开裂时间与文献中报道的实验得到的开裂时间进行比较,评估了现有RC使用寿命预测模型的准确性和适用性。指出了这些模型的缺点,并建议了需要进一步研究的领域。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Service life prediction of reinforced concrete structures subjected to corrosion: a comparative study
PurposeReliable estimations of the extent of corrosion and time required to reach specific safety limits are crucial for assessing the reliability of aging reinforced concrete (RC) bridges. Engineers and decision-makers can use these figures to plan suitable inspection and maintenance operations.Design/methodology/approachAnalytical, empirical and numerical approaches for estimating the service life of corroded RC structures were presented and compared. The concrete cover cracking times, which were predicted by the previously proposed analytical models, were compared with the experimentally obtained cracking times to identify the model/s for RC bridges. The shortcomings and limitations of the existing models are discussed.FindingsThe empirical models typically depend on the rate of corrosion, diameter of steel reinforcement and concrete cover depth and based on basic mathematical formula. In contrast, the analytical and numerical models contain the strength and stiffness properties of concrete as well as type of corrosion products and incorporate more complex mechanical factors. Four existing analytical models were analyzed and their performance was evaluated against existing experimental data in literature. All the considered analytical models were assumed thick-walled cylinder models. The maximum difference between observed cracking time from different test data and calculated cracking time using the developed models is 36.5%. The cracking times extend with increase in concrete cover and decrease with corrosion current density. The development of service life prediction models that considers factors such as heterogeneity of concrete, non-uniform corrosion along rebar, rust production rate and a more accurate representation of the corrosion accommodating region are some of the areas for further research.Research limitations/implicationsOutcome of this paper partially bridge the gap between theory and practice, as it is the basis to estimate the serviceability of corrosion-affected RC structures and to propose maintenance and repair strategies for the structures. For structural design and evaluation, the crack-width criterion is the greatest practical importance, and structural engineers, operators and asset managers should pay close attention to it. Additionally, repair costs for corrosion-induced serviceability failures, particularly concrete cracking and spalling, are significantly higher than those for strength failures. Therefore, to optimize the maintenance cost of RC structures, it is essential to precisely forecast the serviceability of corrosion-affected concrete structures. The lifespan of RC structures may be extended by timely repairs. This helps stake holders to manage the resources.Practical implicationsIn order to improve modeling of corrosion-induced cracking, important areas for future research were identified. Heterogeneity properties of concrete, concept of porous zone (accommodation effect of pores should be quantified), actual corrosion morphology (non-uniform corrosion along the length of rebar), interaction between sustain load and corrosions were not considered in existing models. Therefore, this work suggested for further researches should consider them as input and develop models which have best prediction capacity.Social implicationsThis work has positive impact on society and will not affect the quality of life. Predicting service life of structures is necessary for maintenance and repair strategy plans. Optimizing maintenance strategy is used to extend asset life, reduce asset failures, minimize repair cost, and improve health and safety for society.Originality/valueThe degree of accuracy and applicability of the existing service life prediction models used for RC were assessed by comparing the predicted cracking times with the experimentally obtained times reported in the literature. The shortcomings of the models were identified and areas where further research is required are recommended.
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来源期刊
International Journal of Structural Integrity
International Journal of Structural Integrity ENGINEERING, MULTIDISCIPLINARY-
CiteScore
5.40
自引率
14.80%
发文量
42
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