Underground storage tank blowout analysis: Stability prediction using an artificial neural network

IF 3.7 Q1 PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH

安全科学与韧性(英文) Pub Date : 2023-10-18 DOI:10.1016/j.jnlssr.2023.09.002

Nhat Tan Duong , Van Qui Lai , Jim Shiau , Rungkhun Banyong , Suraparb Keawsawasvong

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引用次数: 0

Abstract

Most geotechnical stability research is linked to “active” failures, in which soil instability occurs due to soil self-weight and external surcharge applications. In contrast, research on passive failure is not common, as it is predominately caused by external loads that act against the soil self-weight. An earlier active trapdoor stability investigation using the Terzaghi's three stability factor approach was shown to be a feasible method for evaluating cohesive-frictional soil stability. Therefore, this technical note aims to expand “active” trapdoor research to assess drained circular trapdoor passive stability (blowout condition) in cohesive-frictional soil under axisymmetric conditions. Using numerical finite element limit analysis (FELA) simulations, soil cohesion, surcharge, and soil unit weight effects are considered using three stability factors (F_c, F_s, and F_γ), which are all associated with the cover-depth ratio and soil internal friction angle. Both upper-bound (UB) and lower-bound (LB) results are presented in design charts and tables, and the large dataset is further studied using an artificial neural network (ANN) as a predictive model to produce accurate design equations. The proposed passive trapdoor problem under axisymmetric conditions is significant when considering soil blowout stability owing to faulty underground storage tanks or pipelines with high internal pressures.

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地下储罐井喷分析:基于人工神经网络的稳定性预测

大多数岩土稳定性研究都与“主动”破坏有关，在这种破坏中，由于土壤自重和外部附加载荷的作用，土壤会发生不稳定。相比之下，对被动破坏的研究并不常见，因为被动破坏主要是由与土壤自重相反的外部荷载引起的。早期使用Terzaghi的三稳定因子方法进行的主动活板门稳定性研究表明，这是一种评估黏结-摩擦土壤稳定性的可行方法。因此，本技术说明旨在扩展“主动”活板门的研究，以评估轴对称条件下黏性-摩擦土中排水圆形活板门的被动稳定性(井喷工况)。利用数值有限元极限分析(FELA)模拟，利用三个稳定因子(Fc、Fs和Fγ)考虑了土壤黏聚力、土壤附加物和土壤单位重量效应，这三个稳定因子都与覆盖深度比和土壤内摩擦角有关。上界(UB)和下界(LB)结果均以设计图表和表格的形式呈现，并使用人工神经网络(ANN)作为预测模型对大型数据集进行进一步研究，以产生准确的设计方程。本文提出的轴对称条件下被动活板门问题在考虑地下储罐或高内压管道故障引起的土壤井喷稳定性时具有重要意义。

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

安全科学与韧性(英文) Management Science and Operations Research, Safety, Risk, Reliability and Quality, Safety Research

CiteScore

8.70

自引率

0.00%

发文量

审稿时长

72 days