浅坡破坏对地下管道永久变形影响的数值研究

IF 1 Q4 ENGINEERING, CIVIL
Mohammed Bouatia, R. Demagh, Z. Derriche
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引用次数: 0

摘要

边坡破坏引起的永久性地面变形会对埋地管道造成灾难性破坏。本文对埋在Aine Tine斜坡(阿尔及利亚米拉)的800 mm输水管道在浅PGD下的行为进行了二维平面应变数值分析,因为它可能是由最近8月7日的地震引发的,2020(M=4.9)。通过应用增量位移来模拟土壤与管道的相互作用,同时重点分析(1)PGD的大小和(2)管道的刚度对管道结构响应的影响。采用弹性完全莫尔-库仑模型模拟土体的力学行为,采用弹性模型模拟钢管的力学行为。管道变形(即平移和椭圆化)和径向内力(即轴向力F୅, 剪切力Fୗ 和弯矩M୆) 结果表明,浅层PGD可以对管道施加与PGD大小成比例的额外载荷。研究发现,刚性管道的土壤变形和管道环上产生的内力更大。结果表明,就椭圆化正常使用极限状态而言,刚性管道比柔性管道更有效。实际上,对于0.5、1和2 m的PGD,柔性管道的椭圆化值分别比刚性管道的计算值高23%、21%和18%。通过本研究中提出的简化线性数值模拟,可以指导工程师和规划者预测管道泄漏的可能原因和破裂机制,这些破裂机制通常会严重破坏管道的正常运行。关键词:土-结构相互作用,边坡破坏,永久地面变形,管道,径向内力,Ovatization
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Numerical Investigation on Buried Pipelines Subjected to Permanent Ground Deformations Due to Shallow Slope Failure
Permanent ground deformations (PGDs) induced by slope failures cause catastrophic damage to buried pipelines. This paper presents a 2D plane-strain numerical analysis of the behavior of a 800 mm water transport pipeline buried in the Aine-Tine slope (Mila, Algeria) subjected to shallow PGD, as it could be triggered by the recent earthquake of August 07th, 2020 (M= 4.9). The analysis is carried out through the application of an incremental displacement to simulate the soil-pipeline interaction while focusing on the effect of (1) the magnitude of the PGD and (2) the rigidity of the pipeline on the structural response of the pipeline. The elasticperfectly Mohr-Coulomb model was used to simulate the soil behavior and the elastic model was used to simulate that of the steel pipe. Pipeline deformations (i.e., translation and ovalization) and radial internal forces’ (i.e., axial forces F୅, shear forces Fୗ and bending moments M୆) results highlighted that shallow PGD can exert additional loads on pipelines that are proportional to the magnitude of the PGD. It has been found that the soil deformations as well as the internal forces induced on the pipeline ring are higher for rigid pipelines. Moreover, the results indicated that rigid pipelines are more effective than flexible ones as far as ovalization-serviceability limit state is concerned. In effect, for PGD magnitudes of 0.5, 1 and 2 m, the ovalization values of the flexible pipeline are, respectively, higher by 23%, 21% and 18% than those calculated for the rigid pipeline. Through a simplified linear numerical simulation such as that presented in this study, engineers and planners could be guided to foresee the possible causes of pipeline leaks and the mechanisms of ruptures that lead very often to severe disruption of pipelines’ normal operation. KEYWORDS: Soil-structure interaction, Slope failure, Permanent ground deformation, Pipelines, Radial internal forces, Ovalization
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来源期刊
CiteScore
2.10
自引率
27.30%
发文量
0
期刊介绍: I am very pleased and honored to be appointed as an Editor-in-Chief of the Jordan Journal of Civil Engineering which enjoys an excellent reputation, both locally and internationally. Since development is the essence of life, I hope to continue developing this distinguished Journal, building on the effort of all the Editors-in-Chief and Editorial Board Members as well as Advisory Boards of the Journal since its establishment about a decade ago. I will do my best to focus on publishing high quality diverse articles and move forward in the indexing issue of the Journal.
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