Modelling the Nonlinear Behavior of the Pot Bearings of Railway Bridge KW51

IF 3.1 2区工程技术 Q2 ENGINEERING, CIVIL

Journal of Bridge Engineering Pub Date : 2023-06-01 DOI:10.1061/jbenf2.beeng-6144

Menno van de Velde, Kristof Maes, Geert Lombaert

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Abstract

Railway bridge KW51 in Leuven, Belgium, has been monitored since October 2018 with the aim of validating various structural health monitoring techniques. The displacement and strain measurements on the structure show a nonlinear behavior, which is attributed to friction in the pot bearings. This paper describes and validates a methodology that allows the observed nonlinear behavior of the pot bearings to be modeled. This is important for understanding and reproducing the bridge behavior under combined train and thermal loading as in, e.g., virtual sensing applications. To this end, a previously developed detailed linear finite-element model of the bridge superstructure is augmented with nonlinear Bouc–Wen elements, representing the bearings. A comparison between the measured and predicted bearing displacements under train loading shows a significant improvement of the response prediction in comparison with the case where the bearings are modeled as roller supports, as assumed in the design. In addition, it is also shown that the model enables a qualitative description of the thermal bridge response.

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KW51铁路桥梁承台非线性行为建模

自2018年10月以来，比利时鲁汶的KW51铁路桥一直在进行监测，目的是验证各种结构健康监测技术。结构的位移和应变测量显示出非线性行为，这归因于锅轴承的摩擦。本文描述并验证了一种方法，该方法允许对观察到的锅轴承的非线性行为进行建模。这对于理解和再现列车和热载荷联合作用下的桥梁行为非常重要，例如，虚拟传感应用。为此，先前开发的桥梁上部结构的详细线性有限元模型与非线性Bouc-Wen单元相结合，代表轴承。列车载荷下实测和预测的轴承位移的比较表明，与设计中假设的轴承建模为滚柱支撑的情况相比，响应预测有了显著的改进。此外，还表明该模型能够定性地描述热桥响应。

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

Journal of Bridge Engineering 工程技术-工程：土木

CiteScore

6.30

自引率

5.60%

发文量

166

审稿时长

6 months

期刊介绍： The Journal of Bridge Engineering publishes papers about all aspects of the art and science of bridge engineering. The journal publishes research that advances the practice and profession of bridge engineering and papers about issues, projects, materials, design, fabrication, construction, inspection, evaluation, safety, performance, management, retrofitting, rehabilitation, repair, and demolition.