Finite Element Analysis of Buried Polyethylene Pipe Subjected to Seismic Landslide

Luo, Xiao; Ma, Jeffrey; Zheng, Jinyang; Shi, Jianfeng

doi:10.1115/1.4026148

Cited by 33 publications

(16 citation statements)

References 9 publications

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“…Finite Element Analysis (FEA) is a modern calculation method for the analysis of structural mechanics that developed rapidly (Luo et al, 2014). It is a numerical technique for finding approximate solutions to boundary value problems for partial differential equations.…”

Section: Finite Element Analysis Used In Pipeline Displacementmentioning

confidence: 99%

Technologies and application of pipeline centerline and bending strain of In-line inspection based on inertial navigation

Cai

Shi

et al. 2017

Transactions of the Institute of Measurement and Control

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Inertial mapping unit (IMU) in-line inspection (ILI) has become routine practice for long-distance buried transport pipelines of oil and gas. It is capable of measuring the pipeline centerline position coordinates and locating the pipeline anomalies, features and fittings to help the oil company manage it. The IMU inspection data also can be used to compute the pipeline bending strain and assess the potential deviation from the original position where endures the extra stress. This paper introduces the main principle, measurement and data processing for IMU ILI. As a key point of calculation for centerline and bending strain, the identification and optimization of the signal are also discussed. At the end of this paper, the developments of IMU ILI are presented. The IMU ILI becomes an important and effective method for pipeline integrity management and safe operation of buried oil and gas pipelines.

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Section: Finite Element Analysis Used In Pipeline Displacementmentioning

confidence: 99%

Technologies and application of pipeline centerline and bending strain of In-line inspection based on inertial navigation

Cai

Shi

et al. 2017

Transactions of the Institute of Measurement and Control

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“…On this basis, considering the influence of slope structure parameters (slope width, slope, and displacement) and pipeline process parameters (burial depth, diameter-thickness ratio, internal pressure) on the mechanical characteristics of the pipeline, and expanding the multi-condition finite element method simulation, the effect of slopes on pipelines has been discussed in a more comprehensive and detailed manner (Lollino et al, 2010;Zhang et al, 2016Zhang et al, , 2018. After mastering the law of pipe mechanics response, the research work gradually turned to the prediction of pipeline safety, such as: discussing the maximum safe length of the pipeline under the above-mentioned multiple working conditions, proposing a prediction formula for the maximum stress of the pipeline, and using actual monitoring data to verify related reliability of conclusions (Ishii et al, 2012;Luo et al, 2014;Li et al, 2016;Vasseghi et al, 2021). In summary, the slope-pipe coupling finite element simulation and monitoring data combined analysis is an effective method for pipeline safety assessment in unstable slope areas.…”

Section: Introductionmentioning

confidence: 99%

Detection and Numerical Simulation of Potential Hazard in Oil Pipeline Areas Based on UAV Surveys

Yan

Yin

et al. 2021

Front. Earth Sci.

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Western China is rich in oil and gas resources, and many oil and gas pipelines are under construction or have been completed. However, many water-related natural hazards, such as landslides, collapses, rockfalls, and debris flows, have developed in the areas passed through by oil and gas pipelines and seriously threaten the operational safety of these pipelines. Therefore, it is urgent to carry out large-scale identification and assessment of pipeline geological hazards. At present, conventional on-site investigation, evaluation, monitoring, and early warning methods are difficult to apply for rapid identification and evaluation of pipeline geological hazards across large-scale areas. Based on this, this study takes the pipeline of Sinopec Marketing South China Branch in Yunnan Province as the research area. In this research, unmanned aerial vehicle (UAV) and photogrammetry technology were used to quickly and accurately obtain multi-phase images of an oil pipeline passing through the study area, and the images were post-processed to obtain multi-phase high-resolution, high-precision digital orthophoto maps and digital terrain models (DTMs) to identify landform changes and deformation. The focus of this research is to propose a set of technical methods for UAV point cloud filtering. The DTMs obtained based on this method can effectively identify unstable areas of oil pipelines. In addition, we have carried out numerical simulations under different motion scenarios in unstable regions, providing scientific support for future geological hazard prevention and mitigation and engineering practices in oil pipeline areas.

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“…Buried pipelines were attacked by natural loads frequently, such as ground settlement, landslide, and debris flow. [1][2][3] The common artificial loads include the repeated load (traffic load), 4 static load (surface load), 5 impact load, 6 and so on. Apparently, the buried pipeline in cities or towns is mainly affected by artificial loads.…”

Section: Introductionmentioning

confidence: 99%

Reliability analysis of buried polyethylene pipeline subject to traffic loads

Sixi

Wei

2019

Advances in Mechanical Engineering

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Due to the increasing number of vehicles in urban areas and the degradation of pavement performance, the failure rate of polyethylene pipeline, across roads, has increased rapidly. Based on relevant data, the traffic loads are regarded as a random variable; also its distribution is determined. First, the nonlinear contact interaction model was established, among traffic loads, soil and buried polyethylene pipeline, using finite element analysis software. Second, considering the decline of the pavement performance, the mechanical characteristics of buried gas pipeline suffering from different traffic loads were analyzed. Based on statistics of vehicle load, the distribution law of its maximum equivalent stress was determined by numerical simulation. Particularly, the strength distribution law of polyethylene pipeline was obtained through experiments. The reliability index of polyethylene pipeline was calculated using central point method and Monte Carlo method. Finally, based on the degradation curve of pavement performance, the remaining life of buried polyethylene pipeline was assessed.

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Finite Element Analysis of Buried Polyethylene Pipe Subjected to Seismic Landslide

Cited by 33 publications

References 9 publications

Technologies and application of pipeline centerline and bending strain of In-line inspection based on inertial navigation

Technologies and application of pipeline centerline and bending strain of In-line inspection based on inertial navigation

Detection and Numerical Simulation of Potential Hazard in Oil Pipeline Areas Based on UAV Surveys

Reliability analysis of buried polyethylene pipeline subject to traffic loads

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