[1]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.[doi:10.6047/j.issn.1000-8241.2018.10.015]
 ZHOU Yawei,ZHANG Zhenyong.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.[doi:10.6047/j.issn.1000-8241.2018.10.015]
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中俄东线天然气管道环焊缝断裂韧性设计

参考文献/References:

[1] ANDREW C,PHIL H. Pipeline defect assessment manual(PDAM):9909A-RPT-001 R1.05[R]. Newcastle upon Tyne:Penspen Limited,2006:1-288.
[2] ANDREW C,PHIL H. The pipeline defect assessmentmanual[C]. Calgary:Proceedings of the 8th InternationalPipeline Conference,2002:IPC2002-07067.
[3] RUDI D,ROBERT A,MURES Z,et al. EPRG Tier 2 guidelinesfor the assessment of defects in transmission pipeline girthwelds[C]. Calgary:Proceedings of the 8th International PipelineConference,2010:IPC2010-31640.
[4] 张振永,周亚薇,张金源. 采用失效评估图确定新建油气管道环焊缝断裂韧性的方法[J]. 焊接技术,2016,46(7):72-76.
ZHANG Z Y,ZHOU Y W,ZHANG J Y. Method for girth weldfracture toughness of newly built pipeline by failure assessmentdiagram[J]. Welding Technology,2016,46(7):72-76.
[5] 高喆慧,帅健,张思弘. 管道焊缝缺陷的定量安全评定与容限尺寸[J]. 油气储运,2015,34(5):488-492,496.
GAO Z H,SHUAI J,ZHANG S H. Quantitative safetyassessment and tolerance size of pipeline weld defects[J]. Oil &Gas Storage and Transportation,2015,34(5):488-492,496.
[6] 王宾,荆洪阳,任晓波. 平面型缺陷断裂评定的BS 7910 标准简介[J]. 压力容器,2006,23(8):7-11.
WANG B,JING H Y,REN X B. Brief introduction of methodsfor assessing the acceptability of plane flaws with reference to BS7910[J]. Pressure Vessel Technology,2006,23(8):7-11.
[7] 王泽恒,吴在盛,赵伟,等. 压力管道失效评定规范及安全评定概况研究[J]. 焊管,2013,36(5):19-23.WANG Z H,WU Z S,ZHAO W,et al. Study on failureassessment norms and safety assessment overview of pressurepipeline[J]. Welded Pipe and Tube,2013,36(5):19-23.[8] 田野. 长输油气管道环焊缝缺陷评价的研究[J]. 内蒙古石油化工,2013,39(19):12-14.
TIAN Y. Long-distance oil and gas pipeline girth weld evaluationstudies[J]. Inner Mongolia Petrochemical Industry,2013,39(19):12-14.
[9] 沙胜义,付春艳,燕冰川,等. 基于无损检测的输油管道环焊缝缺陷安全评估[J]. 管道技术与设备,2017(1):26-29.
SHA S Y,FU C Y,YAN B C,et al. Safety assessment ongirth weld defects of petroleum transmission pipeline based onNDT[J]. Pipeline Technique and Equipment,2017(1):26-29.
[10] 宋小春,黄松岭,赵伟. 天然气长输管道裂纹的无损检测方法[J]. 天然气工业,2006,26(7):103-106.
SONG X C,HUANG S L,ZHAO W. Nondestructive testingtechnique for cracks in long-distance natural gas pipelines[J].Natural Gas Industry,2006,26(7):103-106.
[11] 刘光云,王义. 长输管线环焊缝焊接缺陷的产生及防止[J]. 焊接技术,2010,39(9):65-66.
LIU G Y,WANG Y. Formation and prevention of girth welddefects in long-distance transmission pipeline[J]. WeldingTechnology,2010,39(9):65-66.
[12] Pipelines International. EPRG guidelines on the assessmentof defects in transmission pipeline girth welds – Revision2014[EB/OL].(2015-09-25)[2017-07-30]. https://www.pipelinesinternational.com/2015/09/25/eprg-guidelines-on-theassessment-of-defects-in-transmission-pipeline-girth-weldsrevision-2014/.[13] 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):331-335.
WANG X. The technology status o fracture propagation andcrack arrest of pipelines[J]. Contemporary Chemical Industry,2016,45(2):331-335.
[14] 高惠临. 管线钢管韧性的设计和预测[J]. 焊管,2010,33(12):5-12.GAO H L. The design and prediction of linepipe toughness[J].Weld Pipe and Tube,2010,33(12):5-12.[15] EIBER R J. Fracture control technology for natural gaspipelines[R]. Houston:Technical Toolboxes Inc.,1993:94015614.
[16] 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):1059-1064.
ZHANG Z Y,ZHANG W W,ZHOU Y W,et al. The fracturecontrol design of the OD 1 422 mm buried pipeline in China-Russia Castern Gas Pipeline[J]. Oil & Gas Storage andTransportation,2017,36(9):1059-1064.
[17] PISARSKI H. Assessment of flaws in pipeline girth welds - acritical review[J]. Welding in the World Le Soudage Dans LeMonde,2013,57(6):933-945.
[18] REED R P,MCHENRY H I,KASEN M B. Fracture-mechanicsevaluation of flaws in pipeline girth welds[J]. Weld Res CouncBull,1979(245):1-23.
[19] NAGY G,LUK?CS J,T?R?K I. Assessment of methods ingirth welds of steel pipelines[J]. Materials Science Forum,2005:243-248.
[20] AUCHINCLOSS L. An assessment techniques for defects inunder-and over matched pipeline girth welds[J]. Journal ofNeuroimmunology,2006,180(1-2):193-198.

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备注/Memo

基金项目:中国石油天然气股份有限公司“十二·五”重大科技专项资助项目“第三代大输量天然气管道关键技术研究”,2012E-2801-01。
作者简介:周亚薇,女,1986 年生,工程师,2012 年硕士毕业于中国地质大学(北京)矿产普查与勘探专业,现主要从事油气长输管道线路工程设计和管道材料、可靠性以及风险评估相关研究。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:18732610681,Email:zhouyawei@cnpc.com.cn

更新日期/Last Update: 2018-10-15