A NEW SEISMIC RESISTANT DESIGN METHOD OF BURIED CULVERTS CONSIDERING INTERACTION BETWEEN SOIL AND STRUCTURE

Journal of Japan Society of Civil Engineers, Ser. C (Geosphere Engineering) Pub Date : 1900-01-01 DOI:10.2208/JSCEJGE.75.15

J. Tohda, T. Shimazu, H. Yoshimura, Y. Inoue

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Abstract

1/30-scaled static centrifuge model tests and an elastic FE analysis were conducted to investigate the seismic behavior of buried RC-pipe, FRPM-pipe and box-culvert. In the tests, distributions of normal and tangential earth pressures acting on the surfaces of the three types of model culverts, as well as those of bending strains produced in their walls were precisely measured during cyclic simple shear deformation of the model ground. Test results showed that the tangential earth pressures acting on the culverts were almost null in any case. Numerical results of the FE analysis in which slip and separation at the culvert-ground interface were allowed showed good agreement with the test results. However, the prediction from the current seismic design standard for buried sewer culverts using seismic deformation method based on spring model contradicted the test and numerical results in both earth pressure and bending moment distributions. An analysis using continuum models based on elastic theory clarified that the seismic deformation method has theoretical defects in predicting the earth pressure. Therefore, the FE method used in this study was proposed as a new seismic resistant design method of buried culverts.

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考虑土-结构相互作用的地下涵洞抗震设计新方法

通过1/30比例静力离心模型试验和弹性有限元分析，研究了埋地rc管、frpm管和箱涵的抗震性能。在试验中，精确测量了模型地基在循环单剪切变形过程中作用于三种模型涵洞表面的法向土压力和切向土压力的分布，以及其壁面产生的弯曲应变的分布。试验结果表明，在任何情况下，作用在涵洞上的切向土压力几乎为零。考虑涵地界面滑移和分离的有限元分析数值结果与试验结果吻合较好。然而，现行地下排水涵洞抗震设计规范中基于弹簧模型的地震变形法预测的土压力和弯矩分布与试验和数值结果存在矛盾。基于弹性理论的连续介质模型分析表明，地震变形法在预测土压力方面存在理论缺陷。因此，本文提出采用有限元法作为一种新的地下涵洞抗震设计方法。

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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Journal of Japan Society of Civil Engineers, Ser. C (Geosphere Engineering)

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