Numerical modelling of bridge deck reinforcement corrosion based on analysis of GPR data

Q2 Engineering International Review of Applied Sciences and Engineering Pub Date : 2024-01-18 DOI:10.1556/1848.2023.00740

Tahar Bachiri, A. Khamlichi, M. Hamdaoui, M. Bezzazi, A. Faize

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Abstract

This study explores the impact of corrosion on Ground Penetrating Radar (GPR) responses through practical experiments and numerical modelling, focusing on rebar diameter reduction, corrosion product layer thickness, crack formation and corrosion product filling in vertical and transverse crack. Practical experiments involved GPR testing of reinforced concrete slab. By analyzing B-scans we identify areas with moderate and severe corrosion. Numerical modelling using the Finite Difference Time Domain (FDTD) Method to model GPR signal propagation in a concrete bridge deck with corrosion is applied. Key finding includes a significant 26.70% increase in reflected wave amplitude when corrosion product filling in vertical crack increased by 400%, highlighting its extensive effect on signal GPR propagation. Reduced rebar diameter led to a 9.79% amplitude decrease and a 0.06 ns arrival time delay. Increased corrosion product layer thickness primarily affected arrival time with a 0.06 ns extension but significantly amplified GPR signal amplitude. These findings offer insights for improving GPR based corrosion detection and assessment methods, leading to more robust systems for concrete bridge deck inspection and maintenance. This paper contributes to understanding how corrosion affects the signal that is detected by GPR. This information can be used to improve the way that we manage and assess corrosion in concrete bridge deck.

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基于 GPR 数据分析的桥面钢筋腐蚀数值建模

本研究通过实际实验和数值建模探讨了腐蚀对探地雷达（GPR）响应的影响，重点关注钢筋直径减小、腐蚀产物层厚度、裂缝形成以及垂直和横向裂缝中腐蚀产物的填充。实际实验包括对钢筋混凝土板进行 GPR 测试。通过分析 B 扫描图像，我们确定了中度和严重腐蚀区域。使用有限差分时域 (FDTD) 方法建立数值模型，以模拟 GPR 信号在有腐蚀的混凝土桥面中的传播。主要发现包括：当垂直裂缝中的腐蚀产物填充量增加 400% 时，反射波振幅显著增加 26.70%，突出了其对 GPR 信号传播的广泛影响。钢筋直径减小导致振幅减小 9.79%，到达时间延迟 0.06 ns。腐蚀产物层厚度的增加主要影响到达时间，延时 0.06 ns，但却显著放大了 GPR 信号振幅。这些发现为改进基于 GPR 的腐蚀检测和评估方法提供了启示，从而为混凝土桥面检测和维护提供了更强大的系统。本文有助于了解腐蚀如何影响 GPR 检测到的信号。这些信息可用于改进我们管理和评估混凝土桥面腐蚀的方法。

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来源期刊

International Review of Applied Sciences and Engineering Materials Science-Materials Science (miscellaneous)

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

46 weeks

期刊介绍： International Review of Applied Sciences and Engineering is a peer reviewed journal. It offers a comprehensive range of articles on all aspects of engineering and applied sciences. It provides an international and interdisciplinary platform for the exchange of ideas between engineers, researchers and scholars within the academy and industry. It covers a wide range of application areas including architecture, building services and energetics, civil engineering, electrical engineering and mechatronics, environmental engineering, mechanical engineering, material sciences, applied informatics and management sciences. The aim of the Journal is to provide a location for reporting original research results having international focus with multidisciplinary content. The published papers provide solely new basic information for designers, scholars and developers working in the mentioned fields. The papers reflect the broad categories of interest in: optimisation, simulation, modelling, control techniques, monitoring, and development of new analysis methods, equipment and system conception.