A Whole Process Risk Management System for the Monitoring and Early Warning of Slope Hazards Affecting Gas and Oil Pipelines

Yan, Yan; Xiong, Guanglin; Zhou, Jiaojiao; Ren-he, Wang; Huang, Weixin; Miao, Yuqing; Wang, Renchao; Geng, D. Y.

doi:10.3389/feart.2021.812527

Cited by 8 publications

(6 citation statements)

References 35 publications

(35 reference statements)

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“…In landslide monitoring, the monitoring contents are different with various requirements, among which surface displacement monitoring and inner displacement monitoring are the most important objects. For the inducing factors of geological disasters, the monitoring elements mainly include meteorological conditions such as rainfall, snowmelt, temperature, and evaporation, as well as hydrological conditions such as surface water, river, ditch water level, pore water pressure, soil moisture content, and groundwater level [23]. In this paper, parameters including pipeline additional stress, landslide surface displacement, landslide inner displacement, anti-sliding pile inclination, landslide traction stress and compressive stress, and soil pressure are selected as the monitoring indicators to form a joint monitoring system for pipeline landslide events.…”

Section: Selection Of Monitoring Elementsmentioning

confidence: 99%

A Data-Driven Based Method for Pipeline Additional Stress Prediction Subject to Landslide Geohazards

et al. 2022

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Pipelines that cross complex geological terrains are inevitably threatened by natural hazards, among which landslide attracts extensive attention when pipelines cross mountainous areas. The landslides are typically associated with ground movements that would induce additional stress on the pipeline. Such stress state of pipelines under landslide interference seriously damage structural integrity of the pipeline. Up to the date, limited research has been done on the combined landslide hazard and pipeline stress state analysis. In this paper, a multi-parameter integrated monitoring system was developed for the pipeline stress-strain state and landslide deformation monitoring. Also, data-driven models for the pipeline additional stress prediction was established. The developed predictive models include individual and ensemble-based machine learning approaches. The implementation procedure of the predictive models integrates the field data measured by the monitoring system, with k-fold cross validation used for the generalization performance evaluation. The obtained results indicate that the XGBoost model has the highest performance in the prediction of the additional stress. Besides, the significance of the input variables is determined through sensitivity analyses by using feature importance criteria. Thus, the integrated monitoring system together with the XGBoost prediction method is beneficial to modeling the additional stress in oil and gas pipelines, which will further contribute to pipeline geohazards monitoring management.

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Section: Selection Of Monitoring Elementsmentioning

confidence: 99%

A Data-Driven Based Method for Pipeline Additional Stress Prediction Subject to Landslide Geohazards

et al. 2022

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“…However, this method is not only costly, but also poorly evaluated. More recently, developments in satellite, airborne, and ground monitoring technologies have driven research on remote, real-time monitoring of pipeline geological hazards (Leynes et al 2005;Marinos et al 2019;Yan, Xiong, et al 2022). Real-time monitoring of landslides can provide early warnings for pipeline landslide hazards (Vasconez et al 2010;Lombardi et al 2016;Yan et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Quantitative Estimation of Pipeline Slope Disaster Risk in China

Yan

Zhou

Xie³

et al. 2023

Int J Disaster Risk Sci

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China’s economic development is closely related to oil and gas resources, and the country is investing heavily in pipeline construction. Slope geological hazards seriously affect the long-term safe operation of buried pipelines, usually causing pipeline leakage, property and environmental losses, and adverse social impacts. To ensure the safety of pipelines and reduce the probability of pipeline disasters, it is necessary to predict and quantitatively evaluate slope hazards. While there has been much research focus in recent years on the evaluation of pipeline slope disasters and the stress calculation of pipelines under hazards, existing methods only provide information on the occurrence probability of slope events, not whether a slope disaster will lead to pipeline damage. Taking the 2015 Xinzhan landslide in Guizhou Province, China, as an example, this study used discrete elements to simulate landslide events and determine the risk level and scope for pipeline damage, and then established a pipe-soil coupling model to quantitatively evaluate the impact of landslide hazards for pipelines in medium- and high-risk areas. The results provide a reference for future pipeline disaster prevention and control.

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“…Leaks from underwater pipelines will cause great economic loss and environmental pollution. Therefore, enhancing the safety of underwater gas transmission pipelines and minimizing financial losses require effective and real-time leakage monitoring of underwater pipelines [3][4] . At present, Domestic and foreign researchers have done a lot of work on pipeline leakage monitoring, proposing various methods such as acoustic emission, negative pressure wave, and intelligent underwater robots [5][6] .…”

Section: Introductionmentioning

confidence: 99%

Research on underwater pipeline leakage monitoring based on distributed fiber optic acoustic sensing technology

Luo¹,

Liang²,

Duan³

2023

International Conference on Image, Signal Processing, and Pattern Recognition (ISPP 2023)

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Underwater pipeline transportation, as an important means of natural gas transportation, will cause great economic loss and environmental pollution in case of leakage damage. Aiming at improving the accuracy of pipeline leakage monitoring research, a method was proposed to monitor the leakage process of underwater natural gas pipelines using distributed optical fiber acoustic sensing technology. In this paper, a processing algorithm combining empirical modal decomposition method and wavelet decomposition reconstruction is used to extract the signal frequency domain features. The experimental results show that the frequency domain amplitude of the vibration signal gradually grows as the leakage orifice diameter and internal pipe pressure increase, and the standard deviation of the vibration signal of the pipeline exhibits a quadratic fitting relationship with the size of the leak aperture. The method proposed in this paper has a minimum leak aperture identification error of 7.2%, which can effectively improve the pipeline leak monitoring accuracy.

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A Whole Process Risk Management System for the Monitoring and Early Warning of Slope Hazards Affecting Gas and Oil Pipelines

Cited by 8 publications

References 35 publications

A Data-Driven Based Method for Pipeline Additional Stress Prediction Subject to Landslide Geohazards

A Data-Driven Based Method for Pipeline Additional Stress Prediction Subject to Landslide Geohazards

Quantitative Estimation of Pipeline Slope Disaster Risk in China

Research on underwater pipeline leakage monitoring based on distributed fiber optic acoustic sensing technology

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