PDF下载

[1]程凡菊,李坤,丁融,等.X80管线钢矫顽力与应力关系[J].油气储运,2022,41(11):1332-1340.[doi:10.6047/j.issn.1000-8241.2022.11.013]
　CHENG Fanju,LI Kun,DING Rong,et al.Relationship between coercivity and stress of X80 pipeline steel[J].Oil & Gas Storage and Transportation,2022,41(11):1332-1340.[doi:10.6047/j.issn.1000-8241.2022.11.013]

点击复制

X80管线钢矫顽力与应力关系

《油气储运》[ISSN:1000-8241/CN:13-1093/TE] 卷: 41 期数: 2022年11期页码: 1332-1340 栏目: 工艺与工程出版日期: 2022-11-25

Title:: Relationship between coercivity and stress of X80 pipeline steel

文章编号:: 1000-8241（2022）11-1332-09

作者:: 程凡菊¹; 李坤²; 丁融²; 彭启凤¹; 李玉坤¹; 韩彬¹; 1.中国石油大学（华东）；2.国家管网集团西部管道公司

Author(s):: CHENG Fanju¹; LI Kun²; DING Rong²; PENG Qifeng¹; LI Yukun¹; HAN Bin¹; 1.China University of Petroleum (East China); 2.PipeChina West Pipeline Company

关键词:: X80管线钢; 矫顽力; 力磁耦合; 应力测量; 双向应力状态

Keywords:: X80 pipeline steel; coercivity; mechanical and magnetic coupling; stress measurement; biaxial stress state

分类号:: TE973

DOI:: 10.6047/j.issn.1000-8241.2022.11.013

文献标志码:: A

摘要:: 长输油气管道沿途运行环境复杂，期间异常外载荷易导致局部区域应力集中，增加管道运行风险。基于矫顽力的应力测量方法是评价管道安全裕度、预防管道安全事故的新兴技术。通过深入探究铁磁性材料原子磁矩、磁畴结构、磁滞回线等磁特性，阐明了矫顽力测量应力的力磁耦合机理，介绍了现有的单向应力状态下矫顽力-应力关系表达式，推导了双向应力状态下矫顽力-应力关系模型，并开展实验对X80管线钢单、双向应力状态下的矫顽力-应力关系进行验证。实验结果表明，X80管线钢在单向应力状态下的矫顽力与应力间呈现良好的线性关系，双向应力状态下矫顽力与两向应力均相关，且规律与推导模型相符。研究成果为矫顽力法的现场应用提供了理论和实验依据，证明矫顽力法能够准确测量X80管线钢应力水平，是评估在役管道安全裕度的可靠方法。（图11，表3，参25）

Abstract:: The operation environment along the long-distance oil and gas pipelines is complex, and the abnormal external load during pipeline operation may lead to local stress concentration, which will increase the operation risk of pipeline. The coercivity-based stress measurement method is a new technology to evaluate the safety margin and prevent the safety accidents of pipeline. Herein, the magnetic properties of ferromagnetic materials, such as atomic magnetic moment, domain structure and hysteresis loop, were explored in depth. The mechanism of mechanical and magnetic coupling in coercivity-based stress measurement was clarified. The existing expressions of relationship between coercivity and stress in uniaxial stress state were introduced. The model of relationship between coercivity and stress in biaxial stress state was deduced. Besides, experiments were performed to verify the relationship between coercivity and stress of X80 pipeline steel in the uniaxial and biaxial stress states. The experimental results show that there is a good linear relationship between the coercivity and stress of X80 pipeline steel in uniaxial stress state, the coercivity is related to the biaxial stress in the biaxial stress state, and the laws are consistent with the models derived herein. The research result provides a theoretical and experimental basis for the field application of coercivity-based stress measurement method, which is proved to be capable of accurately measuring the stress of X80 pipeline steel, and it is a reliable method to evaluate the safety margin of in-service pipeline. (11 Figures, 3 Tables, 25 References)

参考文献/References:

[1] 冯耀荣，霍春勇，吉玲康，李鹤林.我国高钢级管线钢和钢管应用基础研究进展及展望[J].石油科学通报，2016，1（1）：143-153. FENG Y R, HUO C Y, JI L K, LI H L. Progress and prospects of research and applications of high grade pipeline steels & steel pipes in China[J]. Petroleum Science Bulletin, 2016, 1(1): 143-153.
[2] 冯耀荣，吉玲康，李为卫，刘迎来，霍春勇.中国X80管线钢和钢管研发应用进展及展望[J].油气储运，2020，39（6）：612-622. FENG Y R, JI L K, LI W W, LIU Y L, HUO C Y. Progress and prospects of research and application of X80 pipeline steel and steel pipe in China[J]. Oil & Gas Storage and Transportation, 2020, 39(6): 612-622.
[3] 梁永宽，杨馥铭，尹哲祺，陈柏杰.油气管道事故统计与风险分析[J].油气储运，2017，36（4）：472-476. LIANG Y K, YANG F M, YIN Z Q, CHEN B J. Accident statistics and risk analysis of oil and gas pipelines[J]. Oil & Gas Storage and Transportation, 2017, 36(4): 472-476.
[4] 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 Y 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.
[5] 陈玉安，周上祺.残余应力X射线测定方法的研究现状[J].无损检测，2001，23（1）：19-22. CHEN Y A, ZHOU S Q. The-state-of-the-art of the study on residual stress measurement by X-ray analysis[J]. Nondestructive Testing, 2001, 23(1): 19-22.
[6] 许光，邢力超，张婷，林健. X射线衍射法测量高温合金波纹管残余应力[J].压力容器，2021，38（7）：32-37. XU G, XING L C, ZHANG T, LIN J. Measurement of residual stress in superalloy bellow using X-ray diffraction technology[J]. Pressure Vessel Technology, 2021, 38(7): 32-37.
[7] 甘文成，王雪梅，倪文波，刘家斌.基于FPGA和LabVIEW的超声波螺栓应力测量系统设计[J].仪表技术与传感器，2019（12）：82-86. GAN W C, WANG X M, NI W B, LIU J B. Design of ultrasonic bolt stress measurement system based on FPGA and LabVIEW[J]. Instrument Technique and Sensor, 2019(12): 82-86.
[8] 路浩，邢立伟，邢敬伟.超声波法焊接残余应力测量技术[J].焊管，2019，42（8）：50-55. LU H, XING L W, XING J W. Ultrasonic method measurement of welding residual stress[J]. Welded Pipe and Tube, 2019, 42(8):50-55.
[9] 沈正祥，陈虎，曹建，牛亚平，王杜.铁磁材料性能无损评估方法研究进展[J].化工机械，2019，46（6）：615-620. SHEN Z X, CHEN H, CAO J, NIU Y P, WANG D. Research progress in non-destructive evaluation of ferromagnetic material properties[J]. Chemical Engineering & Machinery, 2019, 46(6):615-620.
[10] JILES D C. Theory of the magnetomechanical effect[J]. Journal of Physics D: Applied Physics, 1999, 32(15): 1945-1945.
[11] NOVIKOV V F, YATSENKO T A, BASHAREV M S. Coercive force of low-carbon steels as a function of uniaxial stress. Part I[J]. Russian Journal of Nondestructive Testing, 2001, 37(11): 799-804.
[12] NOVIKOV V F, YATSENKO T A, BAKHAREV M S. Coercive force as a function of uniaxial stresses (part 2)[J]. Russian Journal of Nondestructive Testing, 2002, 38(4): 231-237.
[13] 黄东岩，张涛，韩冰，于煦旭.外加应力与残余应力对低碳钢Q235矫顽力的影响[J].磁性材料及器件，2009，40（6）：48-50，70. HUANG D Y, ZHANG T, HAN B, YU X X. Influence of applied stress and residual stress on coercive force of Q235 mild steel[J]. Journal of Magnetic Materials and Devices, 2009, 40(6): 48-50, 70.
[14] IVANOV A M, VASHENKO S S. Changes of coercive force of steel samples with various ductility reached by thermomechanical processing at stretching[J]. Reviews on Advanced Materials Science, 2010, 25(3): 269-272.
[15] 杨理践，吕铮，高松巍.基于矫顽力特性的钢板应力检测技术[J].仪表技术与传感器，2016（11）：31-34. YANG L J, LYU Z, GAO S W. Steel plate stress testing technique based on coercivity characteristics[J]. Instrument Technique and Sensor, 2016(11): 31-34.
[16] VENGRINOVICH V, VINTOV D, PRUDNIKOV A, PODUGOLNIKOV P, RYABTSEV V. Magnetic Barkhausen effect in steel under biaxial strain/stress: influence on stress measurement[J]. Journal of Nondestructive Evaluation, 2019, 38(2): 52.
[17] 罗新，吴伟，李大鹏，王婵，王国成，邬冠华. 20CrMnTi钢渗碳淬火硬化层深度的磁矫顽力检测[J].无损检测，2016，38（7）：47-50. LUO X, WU W, LI D P, WANG C, WANG G C, WU G H. Detection of 20CrMnTi steel carburizing hardening depth by magnetic coercive force[J]. Nondestructive Testing, 2016, 38(7):47-50.
[18] 孙燕华. Q245R钢磁特性对应力的映射规律研究[D].济南：山东大学，2016. SUN Y H. Research on the rules of mapping magnetic properties to stresses in Q245R steel[D]. Jinan: Shandong University, 2016.
[19] 郭子政，胡旭波.应力对铁磁薄膜磁滞损耗和矫顽力的影响[J].物理学报，2013，62（5）：420-425. GUO Z Z, HU X B. Effects of stress on the hysteresis loss and coercivity of ferromagnetic film[J]. Acta Physica Sinica, 2013, 62(5): 420-425.
[20] 任旭虎，孙晓，李德文，苏建楠，艾洁.基于矫顽力与剩磁的铁磁性材料应力测量[J].中国测试，2018，44（3）：16-22. REN X H, SUN X, LI D W, SU J N, AI J. Research on stress measurement of ferromagnetic materials based on coercivity and remanence[J]. China Measurement & Testing Technology, 2018, 44(3): 16-22.
[21] 翁光远，张煜敏，代建波，石韵.管线钢磁力耦合效应及在线无损应力检测[J].西安石油大学学报（自然科学版），2019，34（5）：104-109. WENG G Y, ZHANG Y M, DAI J B, SHI Y. Magnetic coupling effect and on-line nondestructive stress detection of pipeline steel[J]. Journal of Xi'an Shiyou University (Natural Science Edition), 2019, 34(5): 104-109.
[22] 王彦然，樊建春，杨思齐，马昕昱.高压由壬缺陷检测试验及力磁耦合模拟研究[J].石油机械，2022，50（9）：108-116. WANG Y R, FAN J C,YANG S Q, MA X Y. Defect detection test and mechanical-magnetic coupling simulation of high-pressure union[J]. China Petroleum Machinery, 2022, 50(9):108-116.
[23] PINDERA J T, PINDERA M J. Two-dimensional stress states[M]//PINDERA J T, PINDERA M J. Isodyne Stress Analysis. Dordrecht: Springer, 1989: 188-208.
[24] 王力勇.非均分流量负荷的压气站优化运行[J].西安石油大学学报（自然科学版），2021，2：96-102. WANG L Y. Operation optimization of compressor station with uneven flow-rate loads[J]. Journal of Xi'an Shiyou University (Natural Science Edition), 2021, 2: 96-102.
[25] 张建兵，王洋洋，张晓梅，杨紫晔.油套管螺纹关键参数的三坐标测量方法[J].石油机械，2020，48（4）：135-141. ZHANG J B, Wang Y Y, Zhang X M, Yang Z Y. Coordinate measurement method for key parameters of tubing and casing thread[J]. China Petroleum Machinery, 2020, 48(4): 135-141.

相似文献/References:

[1]崔忠浩,刘艳贺,王海涛,等.X80管道环焊缝GTN损伤模型参数标定及应用[J].油气储运,2024,43(09):1.
　CUI Zhonghao,LIU Yanhe,WANG Haitao,et al.Parameter calibration and application of GTN damage model for X80 pipeline girth weld[J].Oil & Gas Storage and Transportation,2024,43(11):1.
[2]崔忠浩,刘艳贺,王海涛,等.X80管道环焊缝GTN损伤模型参数标定及应用[J].油气储运,2024,43(09):1022.[doi:10.6047/j.issn.1000-8241.2024.09.007]
　CUI Zhonghao,LIU Yanhe,WANG Haitao,et al.Parameter calibration and application of GTN damage model for girth weld in X80 pipeline[J].Oil & Gas Storage and Transportation,2024,43(11):1022.[doi:10.6047/j.issn.1000-8241.2024.09.007]
[3]李加庆何帅震赵子峰冯智雨尹鹏博滕霖江莉龙.水-氧-应力关联作用对X80管线钢液氨应力腐蚀行为的影响[J].油气储运,2025,44(03):1.
　LI Jiaqing,HE Shuaizhen,ZHAO Zifeng,et al.The Influence of Water-Oxygen-Stress Interaction on the Stress Corrosion Behavior of Liquid Ammonia in X80 Pipeline Steel[J].Oil & Gas Storage and Transportation,2025,44(11):1.
[4]李加庆,何帅震,赵子峰,等.水-氧-应力联合作用对X80液氨管道应力腐蚀的影响实验[J].油气储运,2025,44(03):271.[doi:10.6047/j.issn.1000-8241.2025.03.003]
　LI Jiaqing,HE Shuaizhen,ZHAO Zifeng,et al.Water-oxygen-stress coupled effects on liquid ammonia stress corrosion behavior in X80 pipeline steel[J].Oil & Gas Storage and Transportation,2025,44(11):271.[doi:10.6047/j.issn.1000-8241.2025.03.003]

备注/Memo

程凡菊，女，1998年生，在读硕士生，2021年毕业于中国石油大学（华东）材料成型及控制工程专业，现主要从事焊接残余应力检测与评价技术方面的研究工作。地址：山东省青岛市黄岛区长江西路66号，266580。电话：15063078230。Email：cfj1998@126.com
（收稿日期：2021-11-10；修回日期：2022-04-25；编辑：张雪琴）

更新日期/Last Update: 2022-11-25