Structural integrity of aging steel bridges by 3D laser scanning and convolutional neural networks

Georgios Tzortzinis, Angelos Filippatos, Jan Wittig, Maik Gude, Aidan Provost, Chengbo Ai, Simos Gerasimidis
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Abstract

For steel bridges, corrosion has historically led to bridge failures, resulting in fatalities and injuries. To enhance public safety and prevent such incidents, authorities mandate in-situ evaluation and reporting of corroded members. The current inspection and evaluation protocol is characterized by intense labor, traffic delays, and poor capacity predictions. Here we combine full-scale experimental testing of a decommissioned girder, 3D laser scanning, and convolutional neural networks (CNNs) to introduce a continuous inspection and evaluation framework. Classification and regression CNNs are trained on a databank of 1,421 naturally inspired corrosion scenarios, generated computationally based on point clouds of three corroded girders collected in lab conditions. Results indicate low errors of up to 2.0% and 3.3%, respectively. The methodology is validated on eight real corroded ends and implemented for the evaluation of an in-service bridge. This framework promises significant advancements in assessing aging bridge infrastructure with higher accuracy and efficiency compared to analytical or semi-analytical approaches. Dr Georgios Tzortzinis and colleagues use a combination of experimental testing and 3D laser scanning to describe the corrosion profile of bridge girders. Their results demonstrate how laser scanners and convolutional neural networks can provide accurate predictions on the structural capacity of ageing steel bridges.

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通过三维激光扫描和卷积神经网络分析老化钢桥的结构完整性。
对于钢结构桥梁而言,锈蚀历来是导致桥梁垮塌并造成人员伤亡的原因。为了加强公共安全并防止此类事故的发生,有关部门强制要求对锈蚀构件进行现场评估和报告。目前的检查和评估方案的特点是劳动强度大、交通延误和能力预测差。在这里,我们将退役大梁的全尺寸实验测试、三维激光扫描和卷积神经网络(CNN)结合起来,引入了一个连续检查和评估框架。根据在实验室条件下采集的三根被腐蚀大梁的点云,通过计算生成了 1421 种自然启发的腐蚀情况数据库,并在此数据库中对分类和回归 CNN 进行了训练。结果表明,误差分别低至 2.0% 和 3.3%。该方法在八个真实的腐蚀端上进行了验证,并用于评估一座在役桥梁。与分析或半分析方法相比,该框架有望以更高的准确性和效率评估老化的桥梁基础设施。
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