Structural Modeling of Cross-Frame Behavior in Steel Girder Bridges

2019 12th International Conference on Developments in eSystems Engineering (DeSE) Pub Date : 2019-10-01 DOI:10.1109/DeSE.2019.00117

Y. Almoosi, J. McConnell, N. Oukaili

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引用次数: 3

Abstract

Cross-Frames and diaphragms are essential structural elements for stability during construction (and sometimes during the service life) of steel bridge systems. In horizontally curved and skew bridges, these braces can engage adjacent girders to act as a system to resist the potentially large forces and torques caused by the curved or skewed geometry. However, because of their role in laterally transmitting live load forces, they can produce fatigue cracks at their connections to the girders. This paper investigates a method for evaluating the distribution of fatigue stress ranges using finite element analysis (FEA), through user-defined subroutines in conjunction with commercial FEA software. Data from field testing under various load passes of a weighed load vehicle of a skewed steel girders bridge are used to validate the results. A case study of an intermediate cross-frame was adapted in order to show the advantage of using this stress analysis methodology, which locates the stress concentration regions where distortion-induced fatigue cracks may originate. This knowledge can then be applied in later work to assess and optimize the fatigue performance of typical bridges and connection details.

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钢梁桥跨框架性能的结构建模

交叉框架和横隔板是钢桥系统在施工期间(有时在使用寿命期间)保持稳定的基本结构元件。在水平弯曲和倾斜的桥梁中，这些支撑可以使相邻的梁作为一个系统来抵抗由弯曲或倾斜几何形状引起的潜在的大力和扭矩。然而，由于它们横向传递活载力的作用，它们在与梁的连接处可能产生疲劳裂纹。本文研究了一种利用有限元分析(FEA)评估疲劳应力范围分布的方法，该方法通过用户自定义子程序与商业有限元分析软件相结合。采用斜交钢梁桥称重车不同荷载道的现场试验数据对结果进行了验证。为了展示使用这种应力分析方法的优势，采用了中间交叉框架的案例研究，该方法定位了变形引起的疲劳裂纹可能产生的应力集中区域。这些知识可以应用到以后的工作中，以评估和优化典型桥梁的疲劳性能和连接细节。

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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2019 12th International Conference on Developments in eSystems Engineering (DeSE)

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