PDF下载

[1]蒋庆梅　张小强　余志峰.中俄东线黑河—长岭段线路可靠性复核[J].油气储运,2020,39(12):1350-1356.[doi:10.6047/j.issn.1000-8241.2020.12.005]
　JIANG Qingmei,ZHANG Xiaoqiang,YU Zhifeng.Recheck on reliability of Heihe-Changling Section of China-Russia Eastern Gas Pipeline[J].Oil & Gas Storage and Transportation,2020,39(12):1350-1356.[doi:10.6047/j.issn.1000-8241.2020.12.005]

点击复制

中俄东线黑河—长岭段线路可靠性复核

《油气储运》[ISSN:1000-8241/CN:13-1093/TE] 卷: 39 期数: 2020年12期页码: 1350-1356 栏目: 完整性与可靠性出版日期: 2020-12-31

Title:: Recheck on reliability of Heihe-Changling Section of China-Russia Eastern Gas Pipeline

文章编号:: 1000-8241（2020）12-1350-07

作者:: 蒋庆梅　张小强　余志峰; 中国石油天然气管道工程有限公司

Author(s):: JIANG Qingmei; ZHANG Xiaoqiang; YU Zhifeng; China Petroleum Pipeline Engineering Corporation

关键词:: 中俄东线; 线路设计; 可靠性; 性能指标; 失效概率

Keywords:: China-Russia Eastern Gas Pipeline; route design; reliability; performance index; failure probability

分类号:: TE88

DOI:: 10.6047/j.issn.1000-8241.2020.12.005

文献标志码:: A

摘要:: 中俄东线天然气管道黑河—长岭段初步设计阶段的可靠性评价，管材基础数据来自试制钢管，环焊缝数据则参考焊接工艺适应性评价结果及以往工程统计数据。管道投产后，需要校验批量供货钢管相对试制钢管的性能差异及其对管道服役可靠性的影响，以及全自动焊的规模推广对管道可靠性的影响。基于新的基础参数，对比了试制钢管与批量供货钢管的性能参数，分析了全自动焊接环焊缝力学参数及缺欠数据，并采用最新数据复核管道的服役可靠性。结果表明：试制钢管与批量供货钢管的力学性能指标存在差异，但均满足标准要求；全自动焊提高了环焊缝质量，焊缝性能指标均高于标准要求；钢管性能波动直接影响管段的失效概率值，且随着服役年限的增加，外腐蚀引起的管道失效概率将逐步增大，但在30 年服役期内，按照目前的设计、材料、施工、运行、维护标准，管道能够满足服役可靠性要求。（图12，表3，参24）

Abstract:: In the reliability assessment of the Heihe-Changling Section of China-Russia Eastern Gas Pipeline at the preliminarydesign stage, the basic data of the pipeline sourced from trial-produced steel pipes, while the girth weld data referenced thewelding process adaptability assessment results and previous engineering statistical data. After the pipeline commissioning, itis necessary to check the performance difference between the batch supply steel pipes and the trial-produced steel pipes andthe impact on the service reliability of the pipeline, as well as the impact of automatic welding on the reliability of the pipeline.Based on the new basic parameters, the performance parameters of trial-produced steel pipes and batch-supplied steel pipes werecompared, the mechanical parameters and defect data of automatic welding girth welds were analyzed, and the service reliabilityof the pipeline was rechecked with the latest data. The results show that the mechanical properties of trial-produced steel pipesare different from the batch-supplied steel pipes, but all of them meet the standard requirements. Automatic welding improvesthe quality of girth welds, and the weld performance indexes are all higher than the standard requirements. The fluctuation ofsteel pipe performance directly affects the failure probability value of the pipeline section. With the increase of service life, thefailure probability of the pipeline caused by external corrosion will be gradually increased, but within the 30-year service life,the pipeline is estimated to meet the service reliability requirements according to the current design, materials, construction,operation and maintenance standards. (12 Figures, 3 Tables, 24 References)

参考文献/References:

[1] 姜昌亮.中俄东线天然气管道工程管理与技术创新 [J].油气储运，2020，39（2）：121-129. JIANG C L. Management and technological innovation in China-Russia Eastern Gas Pipeline Project[J]. Oil & Gas Storage and Transportation，2020，39（2）：121-129.
[2] 程玉峰.保障中俄东线天然气管道长期安全运行的若干技术思考[J].油气储运，2020，39（1）：1-8. CHENG F. Technical insights into the long-term integrity and sustainability of China-Russia Eastern Gas Pipeline[J]. Oil & Gas Storage and Transportation，2020，39（1）：1-8.
[3] 周亚薇，张振永 .中俄东线天然气管道环焊缝断裂韧性设计 [J].油气储运，2018，37（10）：1174-1179. ZHOU Y W，ZHANG Z Y. The design for the fracture toughness of girth weld in China-Russia Eastern Gas Pipeline[J]. Oil & Gas Storage and Transportation，2018，37（10）：1174-1179.
[4] 帅健.油气管道可靠性的极限状态设计方法[J].石油规划设计， 2002，13（1）：18-21. SHUAI J. The reliability used limit state design method[J]. Petroleum Planning & Engineering，2002，13（1）：18-21.
[5] DONG Y，YU D. Estimation of failure probability of oil and gas transmission pipelines by fuzzy fault tree analysis[J]. Journal of Loss Prevention in the Process Industries，2005，18（2）：83-88.
[6] 温凯，张文伟，宫敬，李恒东，张振永，赵博渊.天然气管道可靠性的计算方法[J].油气储运，2014，33（7）：729-733. WEN K，ZHANG W W，GONG J，LI H D，ZHANG Z Y， ZHAO B Y. Computation of gas pipeline reliability[J]. Oil & Gas Storage and Transportation，2014，33（7）：729-733.
[7] 钱成文，崔健.天然气管道的运行可靠性评价技术[J].油气储运，2005，24（增刊 1）：26-30. QIAN C W，CUI J. Operational reliability evaluation of natural gas pipeline[J]. Oil & Gas Storage and Transportation，2005，24（S1）：26-30.
[8] SHAHANI K，MOHAMMAD A，WANG H. Improving safety through engineering assessments for change in location class[C]. Calgary：11th International Pipeline Conference，2016： IPC 2016-64635.
[9] 王馨艺，王淼，冯瑶，张宗杰.基于事故工况下的天然气干线管道供气可靠性评价[J].油气储运，2019，38（4）：392-397. WANG X Y，WANG M，FENG Y，ZHANG Z J. Evaluation on the gas supply reliability of gas trunk pipelines based on accident condition[J]. Oil & Gas Storage and Transportation，2019，38（4）：392-397.
[10] 李明菲，周利剑，郑洪龙，杨辉，雷铮强，薛鲁宁，等.我国天然气管网系统可靠性评价技术现状[J].油气储运，2015，34（5）：464-468. LI M F，ZHOU L J，ZHENG H L，YANG H，LEI Z Q，XUE L N，et a1. Current reliability assessment techniques for natural gas pipeline networks in China[J]. Oil & Gas Storage and Transportation，2015，34（5）：464-468.
[11] 范慕炜，宫敬，伍阳，邓涛.天然气管网可靠性评价方法研究现状[J].油气储运，2015，34（4）：343-348. FAN M W，GONG J，WU Y，DENG T. Research status of reliability evaluation of gas pipeline network[J]. Oil & Gas Storage and Transportation，2015，34（4）：343-348.
[12] 张宗杰，谢青青，文江波，王喜.干线天然气管道运行可靠性评价方法[J].油气储运，2014，33（8）：807-812. ZHANG Z J，XIE Q Q，WEN J B，WANG X. Reliability evaluation method for gas trunk line[J]. Oil & Gas Storage and Transportation，2014，33（8）：807-812.
[13] 赵新伟，池强，张伟卫，杨峰平，许春江.管径 1 422 mm的 X80焊管断裂韧性指标[J].油气储运，2017，36（1）：37-43. ZHAO X W，CHI Q，ZHANG W W，YANG F P，XU C J. Fracture toughness indicators of OD 1 422 mm X80 welded steel pipe[J]. Oil & Gas Storage and Transportation，2017，36（1）：37-43.
[14] 吉玲康，霍春勇，李鹤.我国高压长输天然气管道的断裂控制[J].石油管材与仪器， 2016，2（6）：1-10. JI L K，HUO C Y，LI H. Fracture control for high pressure natural gas pipeline with long distance in China[J]. Petroleum Instruments，2016，2（6）：1-10.
[15] 霍春勇，李鹤，张伟卫，杨坤，池强，马秋荣. X80钢级 1 422 mm大口径管道断裂控制技术[J].天然气工业，2016，36（6）：78-83. HUO C Y，LI H，ZHANG W W，YANG K，CHI Q，MA Q R. Fracture control technology for the X80 large OD 1 422 mm line pipes[J]. Natural Gas Industry，2016，36（6）：78-83.
[16] 张伟卫，李鹤，池强，赵新伟，霍春勇，齐丽华，等.外径 1 422 mm的 X80钢级管材技术条件研究及产品开发[J].天然气工业， 2016，36（6）：84-91. ZHANG W W，LI H，CHI Q，ZHAO X W，HUO C Y，QI L H，et al. Technical speci?cations of the X80 large OD 1 422 mm line pipes and the corresponding product development[J]. Natural Gas Industry，2016，36（6）：84-91.
[17] WEN K，GONG J，ZHAO B Y，ZHANG W W. The reliability-based assessment of an in-service X80 natural gas pipeline in China[C]. Calgary：10th International Pipeline Conference，2014：V004T13A007.
[18] ZHANG S W，ZHOU W X. An ef?cient methodology for the reliability analysis of corroding pipelines[C]. Calgary：9th International Pipeline Conference，2012：90482.
[19] GONG C Q，ZHOU W X. First-order reliability method-based system reliability analyses of corroding pipelines considering multiple defects and failure modes[J]. Structure and Infrastructure Engineering，2017，13（11）：1451-1461.
[20] 帅义，帅健，刘朝阳.腐蚀管道可靠性评价方法研究[J].石油科学通报，2017，2（2）：288-297. SHUAI Y，SHUANG J，LIU Z Y. Research on the reliability methods of corroded pipeline[J]. Petroleum Science Bulletin， 2017，2（2）：288-297.
[21] 孙春梅，李琴，黄志强，汤海平，肖祥.基于 Monte Carlo方法的腐蚀管道可靠性分析[J].油气储运，2015，34（8）：811-816. SUN C M，LI Q，HUANG Z Q，TANG H P，XIAO X. Reliability analysis of corroded pipelines based on Monte Carlo method[J]. Oil & Gas Storage and Transportation，2015，34（8）：811-816.
[22] 张强，杨玉锋，郑洪龙，程万洲.第三方挖掘作用下管道可靠性评价研究[J].中国安全生产科学技术，2017，13（2）：143-147. ZHANG Q，YANG Y F，ZHENG H L，CHENG W Z. Study on reliability evaluation of pipeline under the effect of third-party excavation[J]. Journal of Safety Science and Technology，2017， 13（2）：143-147.
[23] 罗更生，周煜.含裂纹油气管道可靠性评定方法及敏感性分析[J].石油学报， 2011，32（6）：1083-1087. LUO G S，ZHOU Y. A reliability assessment method of crack-containing oil-gas pipelines and its sensitivity analysis[J]. Acta Petrolei Sinica，2011，32（6）：1083-1087.
[24] CALEYO F，GONZAL J L，HALLEN J M. A study on the reliability assessment methodology for pipelines with active corrosion defects[J]. International Journal of Pressure Vessels and Piping，2002，79（1）：77-86.

相似文献/References:

[1]刘俊峰,龙世华.GIS技术在油气管道线路工程设计中的应用[J].油气储运,2006,25(4):41.[doi:10.6047/j.issn.1000-8241.2006.04.011]
　LIU Junfeng,LONG Shihua.Application of GIS Technology in Pre-Engineering Design of Long Distance Pipeline[J].Oil & Gas Storage and Transportation,2006,25(12):41.[doi:10.6047/j.issn.1000-8241.2006.04.011]
[2]李朝,史航.山区地段长输管道线路设计要点[J].油气储运,2002,21(12):27.[doi:10.6047/j.issn.1000-8241.2002.12.007]
　LI Chao,SHI Hang.The Design Key Point on Mountainous Pipeline[J].Oil & Gas Storage and Transportation,2002,21(12):27.[doi:10.6047/j.issn.1000-8241.2002.12.007]
[3]张维尧.埋地管道坚曲线的精确计算与布设[J].油气储运,1988,7(1):15.[doi:10.6047/j.issn.1000-8241.1988.01.004]
　Zhang Weiyao.Precise Calculation and General Distribution of the Vertical Curves for Buried Pipelines[J].Oil & Gas Storage and Transportation,1988,7(12):15.[doi:10.6047/j.issn.1000-8241.1988.01.004]
[4]张振永,孟献强,孙学军,等.中俄东线站场工艺管道用高钢级低温钢管韧性指标[J].油气储运,2018,37(4):435.[doi:10.6047/j.issn.1000-8241.2018.04.012]
　ZHANG Zhenyong,MENG Xianqiang,SUN Xuejun,et al.Toughness index of low-temperature pipe of high steel grade used for the process pipelines at the station of China-Russia eastern natural gas pipeline[J].Oil & Gas Storage and Transportation,2018,37(12):435.[doi:10.6047/j.issn.1000-8241.2018.04.012]
[5]赵国辉.长输油气管道自控技术的发展与中俄东线SCADA系统[J].油气储运,2020,39(01):1.
　ZHAO Guohui.Development of long-distance oil and gas pipeline automatic control technology and SCADA system for China–Russia Eastern Gas Pipeline [J].Oil & Gas Storage and Transportation,2020,39(12):1.
[6]闫锋,欧阳欣,王鹏宇,等.输气管道干线强度设计原则[J].油气储运,2016,35(10):1112.[doi:10.6047/j.issn.1000-8241.2016.10.016]
　YAN Feng,OUYANG Xin,WANG Pengyu,et al.Strength design principles for main gas pipelines[J].Oil & Gas Storage and Transportation,2016,35(12):1112.[doi:10.6047/j.issn.1000-8241.2016.10.016]
[7]郑健峰　李睿　富宽　于智博　陈朋超　赵晓明　贾光明.直径1 422 mm管道投产前自动力内检测器研制与应用[J].油气储运,2020,39(01):1.
　ZHENG Jianfeng,LI Rui,FU Kuan,et al.Development and application of self-driven inner detector for D1 422 mm pipelines before operation[J].Oil & Gas Storage and Transportation,2020,39(12):1.
[8]王巨洪　姜有文　滕延平.中俄东线阴极保护远程监控系统的建设实践[J].油气储运,2020,39(01):1.
　WANG Juhong,JIANG Youwen,TENG Yanping.Construction practice of remote monitoring system for cathodic protection in China–Russia Eastern Gas Pipeline[J].Oil & Gas Storage and Transportation,2020,39(12):1.
[9]刘阳　李雨佳　牛亚琨　王天祺.中俄东线无损检测技术及AUT质量控制体系[J].油气储运,2020,39(中俄东线):1.[doi:10.6047/j.issn.1000-8241.2020.00.000]
　LIU Yang,LI Yujia,NIU Yakun,et al.NDT technology and AUT quality control system applied in China-Russia Eastern Gas Pipeline Project[J].Oil & Gas Storage and Transportation,2020,39(12):1.[doi:10.6047/j.issn.1000-8241.2020.00.000]
[10]张振永,张文伟,周亚薇,等.中俄东线OD 1 422 mm 埋地管道的断裂控制设计[J].油气储运,2017,36(9):1059.[doi:10.6047/j.issn.1000-8241.2017.09.013]
　ZHANG Zhenyong,ZHANG Wenwei,ZHOU Yawei,et al.The fracture control design of the OD 1 422 mm buried pipeline in China-Russia Eastern Gas Pipeline[J].Oil & Gas Storage and Transportation,2017,36(12):1059.[doi:10.6047/j.issn.1000-8241.2017.09.013]

备注/Memo

收稿日期： 2020-03-09；修回日期： 2020-09-16；
基金项目：中国石油天然气集团有限公司重大专项“智慧管网建设运行关键技术研究与应用”，2019E-20。
作者简介：蒋庆梅，女，1986年生，高级工程师， 2010年硕士毕业于东北大学材料加工专业，现主要从事油气长输管道工程设计，管材、焊接技术研究及可靠性评价等工作。地址：河北省廊坊市广阳区和平路 146号管道设计大厦， 065000。电话： 15233166192。 Email：jiangqingmei@cnpc.com.cn
编辑：刘朝阳

更新日期/Last Update: 1900-01-01