[1]付 超,等.极寒地区油气管线建设研究现状[J].焊管,2019,42(5):1-9.[doi:10.19291/j.cnki.1001-3938.2019.5.001]
 FU Chao,SI Yi,et al.Research Status of Oil and Gas Pipeline Construction in Arctic Region[J].,2019,42(5):1-9.[doi:10.19291/j.cnki.1001-3938.2019.5.001]
点击复制

极寒地区油气管线建设研究现状()
分享到:

《焊管》[ISSN:1001-3938/CN:61-1160/TE]

卷:
42
期数:
2019年第5期
页码:
1-9
栏目:
综述
出版日期:
2019-05-28

文章信息/Info

Title:
Research Status of Oil and Gas Pipeline Construction in Arctic Region
文章编号:
10.19291/j.cnki.1001-3938.2019.5.001
作者:
付 超1 2司 译1李学达2罗天宝1
1. 山东胜利钢管有限公司, 山东 淄博255082;
2. 中国石油大学(华东), 山东 青岛 266580
Author(s):
FU Chao1 2 SI Yi1 LI Xueda2 LUO Tianbao1
1. Shandong Shengli Steel Pipe Co., Ltd., Zibo 255082, Shandong, China;
2. China University of Petroleum, Qingdao 266580, Shandong, China
关键词:
焊管大应变钢管低温管线断裂韧性
Keywords:
welded pipe large strain steel pipe low temperature pipeline fracture toughness
分类号:
TG457.6
DOI:
10.19291/j.cnki.1001-3938.2019.5.001
文献标志码:
A
摘要:
为了更好地开发北极等极寒地区蕴藏的巨量石油天然气资源,从北极地区的油气资源及分布情况入手,对当前极地油气管线建设所面临的极寒温度下大壁厚管线钢管的脆性断裂、穿越冻土层导致的钢管大变形等技术难题进行了分析和研究,总结了国外极地管线以及我国高寒地区低温管线的建设现状。结论指出,极寒温度下大壁厚管线钢管焊接接头的脆化机理与抗应变管线钢管的研究是建设长距离极地油气输送管线必须重点关注的方向。
Abstract:
In order to better develop huge oil and gas resources in the arctic and other extremely cold areas, starting with the oil and gas resources and distribution in the arctic region, the brittle fracture of large thickness pipeline steel pipe at extremely cold temperature and the large deformation of steel pipe through tundra were analyzed and studied, and the construction status of polar pipeline of foreign countries and low temperature pipeline of China were summarized. The conclusion indicated that the in the construction of long-distance polar oil and gas transmission pipelines, embrittlement mechanism of welded joints of large thickness pipeline steel pipe and the study of anti-strain pipeline steel pipes at extremely cold temperatures were the directions that should be focused on.

参考文献/References:

[1] BIRD K J, CHARPENTIER R R , GAUTIER D L, et al. Circum-Arctic resource appraisal: estimates of undiscovered oil and gas north of the arctic circle[R/OL].
https://doi.org/10.3133/fs20083049,2018-11-30.
[2] GAUTIER D L, BIRD K J, CHARPENTIER R R, et al. Assessment of undiscovered oil and gas in the Arctic[J]. Science, 2009, 324(5931): 1175-1179.
[3] BAI Q, BAI Y. Subsea Pipeline Design, Analysis, and Installation[J]. Subsea Pipeline Design Analysis &Installotion,2014,138(4587): 255-281.
[4] HARSEM ?覫, EIDE A, HEEN K. Factors influencing future oil and gas prospects in the Arctic[J]. Energy policy, 2011, 39(12): 8037-8045.
[5] SINGH R. Arctic pipeline planning:design, construction, and equipment[M]. [s.l.]:Elsevier, 2013.
[6] DEGEER D, NESSIM M. Arctic pipeline design considerations[C]//ASME 2008 27th International Conference on Offshore Mechanics and Arctic Engineering. [s.l.]:American Society of Mechanical Engineers, 2008:583-590.
[7] FERINO J, FONZO A, DI BIAGIO M, et al. Onshore pipeline high-grade steel for challenge utilization[J]. International Journal of Offshore and Polar Engineering, 2015, 25(4):272-280.
[8] HORN A M, HAUGE M. Material challenges for arctic offshore applications, a reliability study of fracture of a welded steel plate based on material toughness data at
-60℃[C]//The Twenty-first International Offshore and Polar Engineering Conference. Hawaii, USA:International Society of Offshore and Polar Engineers, 2011:134-136.
[9] 金坤, 王玮, 苏戬鹏. 俄罗斯油气管道的现状与趋势[J]. 石油科技论坛, 2015, 28(3):16-20.
[10] 韩秀林, 张远生, 孙灵丽, 等. 大直径大壁厚 K65 钢级耐低温直缝埋弧焊管的开发[J]. 焊管, 2014, 37(11):30-34.
[11] REED K, GRANT B, ANDERSON C, et al. Timing of canadian project approvals: a survey of major projects[J]. Alberta Law Review, 2016, 54(2): 311-335
[12] SWARZ R S. The Trans-Alaska pipeline system: a systems engineering case study[C]//Complex Systems Design & Management.[s.l.]: Springer International Publishing, 2017:17-27.
[13] COLLINS L E, KLEIN R, BAI D. Development of high strength line pipe for Arctic applications[J]. Canadian Metallurgical Quarterly, 2009, 48(3): 261-270.
[14] LANAN G A, ENNIS J O, EGGER P S, et al. Northstar offshore Arctic pipeline design and construction[C]//Offshore Technology Conference. Houston, Texas: Offshore Technology Conference, 2001.
[15] 冯耀荣, 李鹤林. 管道钢及管道钢管的研究进展与发展方向(下)[J]. 石油规划设计, 2006, 17(1): 1-7.
[16] 杜伟, 李鹤林, 王海涛, 等. 国内外高性能油气输送管的研发现状[J]. 油气储运, 2016, 35(6): 577-582.
[17] 王晓香. 当前管线钢管研发的几个热点问题[J]. 焊管, 2014(4): 5-13.
[18] 王晓香. 2012年以来我国焊管行业的发展形势及几点建议[J]. 焊管, 2014(3): 5-8.
[19] 张骁勇, 毕宗岳, 高惠临, 等. X80大变形管线钢的预应变脆化[J]. 焊管, 2013, 36(8): 12-16.
[20] 罗天宝. 湖南胜利湘钢钢管有限公司试制出X80M钢级Φ1 422 mm×25.7 mm、 Φ1 422 mm×30.8mm规格中俄东线直缝埋弧焊管[J]. 钢管,  2017(3): 70.
[21] 韩秀林, 张远生, 孙灵丽, 等. 大直径大壁厚 K65 钢级耐低温直缝埋弧焊管的开发[J]. 焊管, 2014, 37(11):30-34.
[22] EBIHARA K, SAKAMOTO S, HARA T, et al. Mass production of X80 plate for Bovanenkovo-Ukhta(Yamal-Europe) gas pipeline in Russia[C]//2014 10th International Pipeline Conference. Calgary, Alberta, Canada:American Society of Mechanical Engineers, 2014:IPC2014-33372, V003T07A041.
[23] SANCHEZ N, G?譈NG?魻R ?魻 E, LIEBEHERR M, et al. Development of X80M line pipe steel for spiral welded pipes with low temperature toughness and excellent weldability [C]// 2014 10th International Pipeline Conference. Calgary, Alberta, Canada:American Society of Mechanical Engineers, 2014:IPC2014-33502, V003T07A049.
[24] STALLYBRASS C, KONRAD J, MEUSER H, et al. High strength heavy plate optimised for application in remote areas and low-temperature service[C]//2010 8th International Pipeline Conference. Calgary, Alberta, Canada: American Society of Mechanical Engineers, 2010: IPC2010-31227, 391-397.
[25] ZHANG G D, BAI X J, STALHEIM D, et al. Development and production of heavy gauge X80 and high strength X90 pipeline steels utilizing TMCP/optimized cooling process[C]//2014 10th International Pipeline Conference. Calgary, Alberta, Canada:American Society of Mechanical Engineers, 2014: IPC2014-33265, V003T07A037.
[26] 刘文月, 任毅, 高红, 等. 阿拉斯加管道工程用抗大变形X80双相管线钢开发[J]. 上海金属, 2013(6):11-13.
[27] ANDREA D S, 郑磊, 章传国, 等. 具有优异低温韧性和抗应变性能的X80管线钢板/管显微组织识别[C]// 第十届中国钢铁年会暨第六届宝钢学术年会. 上海:宝钢集团股份有限公司, 2015: 110-115.
[28] COLLINS L, BAI D I, HAMAD F, et a1.High strength spiral linepipe for strain-based pipeline designs[C]//The Seventeenth International Offshore and Polar Engineering Conference. Portugal, Lisbon: International Society of Offshore and Polar Engineers, 2007: 2969-2975.
[29] SHINOHARA Y, HARA T, TSURU E, et al. Development of a high strength steel line pipe for strain-based design applications[C]// The Seventeenth International Offshore and Polar Engineering Conference. Portugal, Lisbon: International Society of Offshore and Polar Engineers, 2007: 2980-2986.
[30] 王旭. 油气管道断裂扩展及止裂技术研究[J]. 当代化工, 2016, 45(2): 332-335.

相似文献/References:

[1]马海君.强力焊管的孔型设计[J].焊管,2007,30(4):56.[doi:1001-3938(2007)04-0056-02]
 MA Hai-jun.Pass Design of High-strength Welded Pipe[J].,2007,30(5):56.[doi:1001-3938(2007)04-0056-02]
[2]刘庆才,李 东,黎剑锋.影响输气管线钢管抗H2S性能主要因素的探讨[J].焊管,2007,30(5):54.[doi:1001-3938(2007)05-0054-05]
 LIU Qing-cai,LI Dong,LI Jian-feng.Key Factors Affecting Sour Service Ability of Welded Pipe and Its Domestic Production[J].,2007,30(5):54.[doi:1001-3938(2007)05-0054-05]
[3]彭在美.我国焊接钢管的发展进入重要的战略转折期[J].焊管,2008,31(6):5.[doi:1001-3938(2008)06-0005-10]
 PENG Zai-mei.The Development of China Welded Pipe Steps into the Important Strategic Transition Period[J].,2008,31(5):5.[doi:1001-3938(2008)06-0005-10]
[4]李霄,熊庆人,石凯,等.焊管残余应力研究进展及展望[J].焊管,2009,32(7):12.[doi:1001-3938(2009)07-0012-06]
 LI Xiao,XIONG Qing-ren,SHI Kai,et al.Research Progress and Prospect of Residual Stress in Welded Pipe[J].,2009,32(5):12.[doi:1001-3938(2009)07-0012-06]
[5]马 露 涛.φ720mm焊管平头机夹管装置设计[J].焊管,2009,32(9):47.[doi:1001-3938(2009)09-0047-03]
 MA Lu-tao.Design for φ720mm Welded Pipe Beveling Machine Clamp Pipe Device[J].,2009,32(5):47.[doi:1001-3938(2009)09-0047-03]
[6]耿开博.铝管、不锈钢管的高频感应焊接[J].焊管,2009,32(11):29.[doi:1001-3938(2009)11-0029-03]
 GENG Kai-bo.High-frequency Induction Welding of Aluminum and Stainless Steel Pipes[J].,2009,32(5):29.[doi:1001-3938(2009)11-0029-03]
[7]陈志翔,Jean Paul Boillot,Jeff Noruk.数字激光视觉技术在焊管生产中的应用[J].焊管,2010,33(2):29.[doi:1001-3938(2010)02-0029-04]
 CHEN Zhi-xiang,Jean Paul Boillot,Jeff Noruk.Application of Digital Laser Vision Technology in Welded Pipe Production[J].,2010,33(5):29.[doi:1001-3938(2010)02-0029-04]
[8]黄克坚,苏章卓,甘遂谋,等.焊管机械扩径力的计算[J].焊管,2010,33(12):13.[doi:1001-3938(2010)12-0023-04]
[9]吴庆根.高频焊管生产中管体温度不均造成弯管的防止措施[J].焊管,2011,34(1):51.[doi:1001-3938(2011)01-0051-03]
[10]王晓香.坚持结构调整和科技进步继续向焊管强国迈进[J].焊管,2011,34(2):5.[doi:1001-3938(2011)02-0005-05]
 WANG Xiao-xiang.Go Ahead to the Target of Welded Pipe Powerful Nation by Insisting in Structural Adjustment and Technical Promotion[J].,2011,34(5):5.[doi:1001-3938(2011)02-0005-05]

备注/Memo

备注/Memo:
收稿日期:2018-12-24
基金项目: 淄博市科学技术发展计划“极地服役大壁厚X80螺旋埋弧焊管研究”(项目编号2017kj020007)。
作者简介:付 超(1987—),男,在职博士,发表论文10余篇,主要从事极寒温度下服役的高等级大壁厚管线钢焊接接头的低温脆化机理与预精焊工艺的研究。
更新日期/Last Update: 2019-06-20