油气长输管道地质灾害监测标准分析
Standard Analysis of Geological Disaster Monitoring for Long-Distance Oil and Gas Pipeline
DOI: 10.12677/JOGT.2020.422027, PDF,    科研立项经费支持
作者: 王 婷, 王巨洪, 王学力, 陈健, 王 新, 荆宏远:中国石油管道公司,河北 廊坊;常 青:中国石油北京天然气管道分公司,河北 石家庄
关键词: 油气长输管道地质灾害监测标准风险等级监测等级报警阈值Long-Distance Oil and Gas Pipeline Geological Hazard Monitoring Standard Risk Level Monitoring Level Alarm Threshold
摘要: 为梳理现有油气长输管道地质灾害监测标准存在问题,给出标准使用及标准整合编制建议,收集整理了国内常用的多项地灾监测标准,通过对比分析地灾风险等级划分、监测等级与地灾风险等级对应、各监测技术具体应用条件及方式和本体应力应变监测报警阈值等技术点,提出建议:统一地质灾害风险等级的划分方法及监测等级与地灾风险等级的对应情况,有效指导标准使用者对风险的判断及监测等级的选择,同时针对不同地灾类型的多种监测技术手段,明确在何种条件下应用及具体实施方式,以及应综合考虑管材、管径、壁厚、焊缝、环境、失效模式等各种因素确定预警阈值,评估管道的完整性。
Abstract: In order to find out the existing problems of geological hazard monitoring standards for long- distance oil and gas pipelines, and to propose suggestions for standard usage and standard integration, several commonly used monitoring standards for geological hazards in China are collected and sorted out. Through technical points comparative analysis, the risk classification of geological hazards, the correspondence between monitoring level and disaster risk level, the specific application conditions and modes of monitoring technologies, and the alarm threshold of stress and strain monitoring are analyzed. Recommendations are: Unify the method of dividing the risk grade of geological hazards and the corresponding situation between the monitoring grade and the risk grade of geological hazards, effectively guide the standard users to judge the risk and choose the monitoring grade. At the same time, according to different types of local hazards, it is clear under what conditions and specific implementation methods, and it is necessary to consider the pipe material, pipe diameter, wall thickness, welding seam and environment comprehensively. The early warning threshold is determined by various factors such as failure mode and so on, and the integrity of pipeline is evaluated.
文章引用:王婷, 王巨洪, 王学力, 陈健, 王新, 荆宏远, 常青. 油气长输管道地质灾害监测标准分析[J]. 石油天然气学报, 2020, 42(2): 151-156. https://doi.org/10.12677/JOGT.2020.422027

参考文献

[1] 徐安全. 浅谈地质灾害监测技术现状及发展趋势[J]. 企业技术开发, 2014(19): 117-118.
[2] 宋帅, 李家鹤. 地质灾害监测技术发展趋势研究[J]. 黑龙江国土资源, 2015(9): 694.
[3] Pipeline and Hazardous Materials Safety Administration. PHMSA Strategic Plan. https://www.phmsa.dot.gov/data-and-statistics/pipeline/pipeline-incident-flagged-files
[4] 杨明生, 王国勇, 陈刚, 等. 中石化油气长输管道地质灾害监测技术介绍[J]. 江汉石油职工大学学报, 2017, 30(5): 62-63.
[5] 韩子夜, 薛星桥. 地质灾害监测技术现状与发展趋势[J]. 中国地质灾害与防治学报, 2005, 16(3): 138-141.
[6] Deschamps, B., Henschel, M.D. and Robert, G. (2016) Quantification and Extension of Lateral Ground Movement Detection Capabilities Derived from Synthetic Aperture Radar. PRCI ROW-6-2 Final Report.
[7] Rodolfo, B., Sancio, A.H., et al. (2014) Evaluation of Current ROW Threat Monitoring, Applications, and Analysis Technology. PRCI PR-420-123712 Final Report.
[8] 马士彪. 浅谈地质灾害监测技术现状与发展趋势[J]. 现代农业研究, 2015(6): 62.
[9] Robert, G. (2017) Pipeline ROW Ground Movement Monitoring from InSAR for the PRCI Satellite Consortium Project. PRCI 2017 Research Exchange Meeting.
[10] 刘鹏程, 王建国. 基于地质灾害监测系统的研究与实现分析[J]. 电子世界, 2017(15): 176.
[11] 梁军. 基于GIS地质灾害监测无线自动化采集传输系统设计分析[J]. 建设科技, 2017(14): 102-103.
[12] Zhang, Z.G., Shen, N.Q., Li, Y.C., et al. (2011) Geological Hazards Risk Evaluation of Pipeline Construction Site Based on Extension Method. International Conference on Pipelines and Trenchless Technology 2011: Sustainable Solutions for Water, Sewer, Gas, and Oil Pipelines, 1667-1676. [Google Scholar] [CrossRef
[13] Moya, J.M., De, L.S. and Giancarlo, M. (2014) Alternative Geohazard Risk Assessment and Monitoring for Pipelines with Limited Access: Amazon Jungle Example. 10th International Pipeline Conference, Calgary, 29 September-3 October 2014. [Google Scholar] [CrossRef
[14] 王洪辉, 李鄢, 庹先国, 等. 地质灾害物联网监测系统研制及贵州实践[J]. 中国测试, 2017, 43(9): 94-99.
[15] Ma, Y.B., Cai, Y.J. and Tan, D.J. (2012) Design and Application of Long Distance Oil & Gas Pipeline Stress & Strain Monitoring Sensor. Advanced Materials Research, 383-390, 1458-1462. [Google Scholar] [CrossRef
[16] 凌骐, 张轩, 孔松, 等. 水电工程地质灾害监测预警与应急管理系统设计及应用[J]. 水电与抽水蓄能, 2017, 3(6): 35-39.
[17] 王洪辉, 徐少波, 庹先国, 等. 地质灾害监测数据自适应对象持久化方法[J]. 计算机工程与设计, 2017, 38(7): 1972-1976.
[18] Aufliɥ, M.J., Komac, M. and Inigoj, J. (2015) Modern Remote Sensing Techniques for Monitoring Pipeline Displacements in Relation to Landslides and Other Slope Mass Movements. In: Environmental Security of the European Cross-Border Energy Supply Infrastructure, Springer, Berlin, 31-48. [Google Scholar] [CrossRef
[19] Malpartida, M. and John, E. (2015) Managing Geohazards in Hard Conditions: Monitoring and Risk Assessment of Pipelines That Crosses Amazonian Jungles and the Andes. ASME International Pipeline Geotechnical Conference.
[20] Read, R.S. (2018) Pipeline Geohazard Assessment—Bridging the Gap between Integrity Management and Construction Safety Contexts. Proceedings of the Biennial International Pipeline Conference.
[21] Li, G.Y., Ma, W. and Wang, X.L. (2015) Frost Hazards and Mitigative Measures Following Operation of Mohe-Daqing Line of China-Russia Crude Oil Pipeline. Rock and Soil Mechanics, 36, 2963-2973.
[22] ASME B31.8-2014 (2014) Gas Transmission and Distribution Piping Systems. The American Society of Mechanical Engineers, New York.