压力、温度和土壤刚度对地质灾害区管道应变需求的综合影响

Ismael Allouche, Qian Zheng, N. Yoosef-Ghodsi, Matt Fowler, S. Adeeb
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引用次数: 0

摘要

由于地质灾害荷载引起的地面变形对管道的分析、设计和评估具有重要意义。一种合适的评估方法是有限元法(FEM),它提供了高效和复杂的结果。Zheng等人(2021)使用有限元分析(FEA)软件Abaqus/Standard提出的方法,通过模拟受不同大小和方向的地面位移影响的埋地钢管的位移控制分析,提供了高度精确的结果。本文旨在通过考虑埋于不同刚度土壤中的钢管内压和温度的变化影响,进一步发展管道应变需求评估。开发的应变需求准则考虑了不同等级钢管的非弹性材料行为,以及考虑土壤塑性的双线土力-位移相互作用(ALA, 2001)。假设在地震动开始之前热膨胀的影响可以忽略不计,则可以通过对具有初始温度和压力载荷的管道进行建模,然后按照一系列步骤进行地震动,从而评估管道载荷。通过对X65级管道进行建模,进行了几个案例研究,这些管道在管道中部的长度范围内受到100至1000 mm不等的地面位移的影响。模拟是在指定的温度升高和内部压力下进行评估的,内部压力需要达到指定最小屈服强度(SMYS)的80%。通过评估不同刚度(低、中、高)土壤中的管道,在不同的地面位移增量下,可以获得每种情况下材料应力/应变响应的准确表示。本研究可为管道内压温度的进一步研究提供指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Combined Effect of Pressure, Temperature and Soil Stiffness on Pipeline Strain Demand in Geohazard Zones
Pipelines subject to ground deformations produced by geohazard loads carry high importance on pipeline analysis, design, and assessment due to risk of structural failure. An appropriate approach for evaluation is the finite element method (FEM), providing efficient and sophisticated results. Methods proposed by Zheng et al. (2021) using finite element analysis (FEA) software Abaqus/Standard provide highly accurate results by simulating a displacement-controlled analysis of buried steel pipes subject to ground displacement of varying magnitudes and direction. This paper aims to further develop this pipe strain demand assessment by including variable effects of internal pressure and temperature of steel pipes buried in soils of different stiffness. The developed strain demand criterion considers inelastic material behaviour for different grades of steel pipe, as well as bi-linear soil force-displacement interaction, accounting for soil plasticity (ALA, 2001). Assuming the effects of thermal expansion are negligible prior to ground motion initiation, the pipe loads can be assessed by modelling a pipeline with initial temperature and pressure loads, followed by a ground motion in a series of steps. Several case studies were performed by modelling an X65 grade pipeline subject to ground displacements varying from 100 to 1000 mm, across a length at the midsection of the pipe. Simulations are assessed with a specified temperature increase, and internal pressure required to induce an operating hoop stress of up to 80% of the specified minimum yield strength (SMYS). By assessing the pipeline in soils of different stiffness (low, intermediate, high) at different increments of ground displacement, an accurate representation of the material stress/strain response can be acquired for each respective case. This research may provide guidance for further studies of pipelines involving internal pressure & temperature.
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