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[1]刘祥元,樊建春,刘书杰,等.深水钻井隔水管磁记忆内检测装置研发及应用*[J].中国安全生产科学技术,2022,18(2):70-74.[doi:10.11731/j.issn.1673-193x.2022.02.010]
 LIU Xiangyuan,FAN Jianchun,LIU Shujie,et al.Development and application of magnetic memory internal detection device for deep-water drilling riser[J].JOURNAL OF SAFETY SCIENCE AND TECHNOLOGY,2022,18(2):70-74.[doi:10.11731/j.issn.1673-193x.2022.02.010]
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深水钻井隔水管磁记忆内检测装置研发及应用*
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《中国安全生产科学技术》[ISSN:1673-193X/CN:11-5335/TB]

卷:
18
期数:
2022年2期
页码:
70-74
栏目:
学术论著
出版日期:
2022-02-28

文章信息/Info

Title:
Development and application of magnetic memory internal detection device for deep-water drilling riser
文章编号:
1673-193X(2022)-02-0070-05
作者:
刘祥元樊建春刘书杰张春杰
(1.中国石油大学(北京),北京 102249;
2.中海石油(中国)有限公司 海南分公司,海南 海口 570311;
3.中海石油(中国)有限公司 深圳分公司,广东 深圳 518067)
Author(s):
LIU Xiangyuan FAN Jianchun LIU Shujie ZHANG Chunjie
(1.China University of Petroleum (Beijing),Beijing 102249,China;
2.Hainan Branch of CNOOC,Haikou Hainan 570311,China;
3.Shenzhen Branch of CNOOC,Shenzhen Guangdong 518067,China)
关键词:
钻井隔水管疲劳损伤磁记忆现场检测
Keywords:
drilling riser fatigue damage magnetic memory on-site detection
分类号:
X937TE952
DOI:
10.11731/j.issn.1673-193x.2022.02.010
文献标志码:
A
摘要:
为了解决深水钻井隔水管裂纹、磨损、疲劳损伤等检测难题,基于磁记忆检测技术研制1种内检测器。其主要结构包括:数据采集腔,周向布置的60路GMR高灵敏度传感器,导向支撑轮,吊装牵拉钩等。该设备可以在不拆卸浮力块的情况下完成隔水管内壁的覆盖式扫查。结果表明:检测器具备较高的可靠性,操作简单、检测效率高;检测数据可以有效反映隔水管局部损伤、应力集中异常并对其实现精准定位,为判断隔水管早期损伤提供基础;实现深水钻井隔水管缺陷和疲劳状态的易检测、早预警,解决现场检测难题,具备良好的应用前景。
Abstract:
In order to solve the detection problems such as cracks,wear and fatigue damage of deep-water drilling riser,an internal detector based on the magnetic memory detection technology was developed.Its main structure included the data acquisition cavity,the 60-channel GMR high-sensitivity sensor arranged in circumferential direction,the guide support wheel,the hoisting pull hook,etc.The device could complete the covering scan of the inner wall of riser without disassembling the buoyancy block.The results showed that the detector had relatively high reliability,simple operation and high detection efficiency.The detection data could effectively reflect the local damage and abnormal stress concentration of the riser and realize the accurate positioning,which provides a basis for judging the early damage of riser.It realized the easy detection and early warning on the defects and fatigue status of deep-water drilling riser and solved the problem of on-site detection,which has good application prospects.

参考文献/References:

[1]周建良,许亮斌.深水钻井隔水管关键技术研究进展[J].中国海上油气,2018,30(4):135-143,213.ZHOU Jianliang,XU Liangbin.Research progress on key technologies of deepwater drilling riser[J].China Offshore Oil & Gas,2018,30(4):135-143,213.
[2]任少铎.卡门涡街的成因及虎门大桥的振动分析[J].物理教师,2020,41(9):57-59,61.REN Shaoduo.The cause of the Carmen Vortex Street and the vibration analysis of Humen Bridge[J].Teacher of Physics,2020,41(9):57-59,61.
[3]刘秀全,邱娜,王向磊,等.基于断裂力学的深水钻井隔水管疲劳失效评估[J].石油工程建设,2020,46(S1):138-144.LIU Xiuquan,QIU Na,WANG Xianglei,et al.Fatigue failure assessment of deepwater drilling riser based on fracture mechanics[J].Petroleum Engineering Construction,2020,46(S1):138-144.
[4]MUKUNDAN H,MODARRES-SADEGHI Y,DAHL J M,et al.Monitoring VIV fatigue damage on marine risers[J].Journal of Fluids and Structures,2009,25(4):617-628.
[5]HUERA-HUARTE F J,Bearman P W.Wake structures and vortex-induced vibrations of a long flexible cylinder—Part 2:Drag coefficients and vortex modes[J].Journal of Fluids and Structures,2009,25(6):991-1006.
[6]盛磊祥,许亮斌,金学义,等.钻井隔水管涡激振动监测装置海上试验[J].中国海上油气,2021,33(1):140-144.SHENG Leixiang,XU Liangbin,JIN Xueyi,et al.Offshore test of drilling riser vortex-induced vibration monitoring device[J].China Offshore Oil and Gas,2021,33(1):140-144.
[7]PETER J D,ROBINSON R,METCALFE T J,et al.Fatigue evaluation of drilling risers for harsh environments and ultra deepwater developments to allow optimised riser life and inspection plans[C]//SPE/IADC Drilling Conference.OnePetro,2005.
[8]冯搏,伍剑波,邱公喆,等.高速漏磁检测方法的发展[J].无损检测,2021,43(2):57-63.FENG Bo,WU Jianbo,QIU Gongzhe,et al.The development of high-speed magnetic flux leakage detection methods[J].Nondestructive Testing,2021,43(2):57-63.
[9]刘瑞庆,李大伟,吴朝来,等.电磁导波与脉冲涡流检测仪[J].仪表技术与传感器,2019(1):34-36,41.LIU Ruiqing,LI Dawei,WU Chaolai,et al.Electromagnetic guided wave and pulse eddy current detector[J].Instrument Technology and Sensor,2019(1):34-36,41.
[10]吴家风,樊建春,胡治斌,等.基于磁记忆检测方法的连续油管刻伤试验研究[J].中国安全生产科学技术,2017,13(9):84-89.WU Jiafeng,FAN Jianchun,HU Zhibin,et al.Research on coiled tubing scratch test based on magnetic memory detection method[J].China Work Safety Science and Technology,2017,13(9):84-89.
[11]胡治斌,樊建春,高维骏,等.基于磁记忆的钻柱损伤井口检测技术[J].石油机械,2017,45(4):27-31.HU Zhibin,FAN Jianchun,GAO Weijun,et al.Drill string damage detection technology based on magnetic memory[J].Petroleum Machinery,2017,45(4):27-31.
[12]孙秉才,樊建春,温东,等.高压管汇冲蚀磨损磁记忆检测试验研究[J].石油机械,2014,42(6):65-68.SUN Bingcai,FAN Jianchun,WEN Dong,et al.Experimental study on magnetic memory detection of erosion and wear of high pressure manifold[J].Petroleum Machinery,2014,42(6):65-68.
[13]周守为,刘清友.深水钻井隔水管系统力学行为理论及应用研究[M].北京:科学出版社,2016:8-9.
[14]张来斌,樊建春,宋周成,等.基于巨磁阻效应的油井管损伤磁记忆检测诊断技术及工业化应用[J].科技纵览,2015(1):63-65.ZHANG Laibin,FAN Jianchun,SONG Zhoucheng,et al.Magnetic memory detection and diagnosis technology for oil well pipe damage based on giant magnetoresistance effect and its industrial application[J].Overview of Science and Technology,2015(1):63-65.
[15]李衍.焊接接头金属磁记忆法检测国际标准解读[J].无损探伤,2020,44(4):27-31.LI Yan.Interpretation of international standards for metal magnetic memory method testing of welded joints[J].Nondestructive Testing,2020,44(4):27-31.
[16]DUBOV A,KOLOKOLNIKOV S.Assessment of the material state of oil and gas pipelines based on the metal magnetic memory method[J].Journal of the International Institute of Welding,2012,56(3/4):11-19.
[17]杜波夫.金属磁记忆方法-设备和金属结构技术诊断的新方向发展与应用的简要总结、标准化问题[C]//第八届全国无损检测大会会议论文集.2003:543-546.
[18]中华人民共和国国家质量监督检验检疫总局、中国国家标准化管理委员会.无损检测 磁记忆检测 总则:GB/T 26641—2011[S].北京:中国标准出版社,2011:10.
[19]邢海燕.基于磁记忆技术的疲劳损伤评估及寿命预测[D].哈尔滨:哈尔滨工业大学,2007.

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备注/Memo

备注/Memo:
收稿日期: 2021-05-11
* 基金项目: 国家重点研发计划项目(2017YFC0804500)
作者简介: 刘祥元,博士研究生,主要研究方向为安全监测与智能诊断。
通信作者: 樊建春,博士,教授,主要研究方向为石油装备无损检测技术 。
更新日期/Last Update: 2022-03-18