Performance of Bridge Envelope During Earthquake Using Finite Element and Artificial Neural Network Techniques

The Open Civil Engineering Journal Pub Date : 2022-10-19 DOI:10.2174/18741495-v16-e2208100

M. Naji, A. Firoozi

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Abstract

Bridges are one of the most critical parts of a transportation network that may be damaged during earthquakes and it is necessary to have a prediction model for bridge responses under seismic loads that can be extended to other situations. Soil stiffness significantly affects load distribution when soil, piles, abutment, and superstructure all act as a combined system to resist lateral loading on a bridge. A two-dimensional (2D) model of integral abutment bridge (IAB) with soil springs around piles and behind the abutments for 18.3m, 35.4m, and 64.5m spans respectively, was developed with finite element (FE). The input variables were bridge span, backfill height, soil stiffness behind abutment, and soil stiffness around piles. Also, Artificial Neural Network (ANN) was examined for pile lateral force, pile displacement, pile head moment, girder axial force, and abutment moment. Using FE the prediction of critical response for medium span (i.e., 123.6m) and large span (i.e., 249m) by ANN was performed. Findings show that backfill stiffness has an important effect on lateral displacement. The best performance was related to high stiffness backfill with intermediate clay around the pile. Stiffness of clay around the pile has an important effect on lateral displacement, pile lateral force, pile bending moment, girder axial force, and girder bending moment at the abutment.

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基于有限元和人工神经网络技术的桥梁围护结构抗震性能研究

桥梁是交通运输网络中最重要的部分之一，在地震作用下可能受到破坏，有必要建立一个地震荷载作用下桥梁反应的预测模型，并将其推广到其他情况。当桥梁上的土、桩、桥台和上部结构作为一个联合系统来抵抗横向荷载时，土的刚度对荷载分布有显著影响。采用有限元方法，建立了18.3m、35.4m和64.5m跨桩周土弹簧和桥墩后土弹簧的整体桥台桥梁二维模型。输入变量为桥梁跨度、回填高度、桥台后土体刚度和桩周土体刚度。采用人工神经网络对桩侧力、桩位移、桩头弯矩、梁轴力和桥台弯矩进行了分析。采用有限元法对中跨度(123.6m)和大跨度(249m)的临界响应进行了人工神经网络预测。结果表明，充填体刚度对侧移有重要影响。桩周中间粘土的高刚度回填效果最好。桩周土体刚度对桩侧位移、桩侧力、桩弯矩、梁轴力和桥台梁弯矩有重要影响。

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The Open Civil Engineering Journal

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