高频磁耦合有缆钻杆信道建模与仿真分析

doi:10.7623/syxb201811009

石油学报 ›› 2018, Vol. 39 ›› Issue (11): 1292-1298,1316.DOI: 10.7623/syxb201811009

高频磁耦合有缆钻杆信道建模与仿真分析

胡永建, 黄衍福, 石林

中国石油集团钻井工程技术研究院北京 102206

收稿日期:2017-12-11 修回日期:2018-08-24 出版日期:2018-11-25 发布日期:2018-12-10
通讯作者: 胡永建,男,1970年5月生,1992年获西安交通大学学士学位,1995年获北京大学硕士学位,现为中国石油集团钻井工程技术研究院高级工程师,主要从事石油钻井井下仪器及通讯设备研制。Email:huyongjian32788@163.com
作者简介:胡永建,男,1970年5月生,1992年获西安交通大学学士学位,1995年获北京大学硕士学位,现为中国石油集团钻井工程技术研究院高级工程师,主要从事石油钻井井下仪器及通讯设备研制。Email:huyongjian32788@163.com
基金资助:
国家科技重大专项（2016ZX05020-005-001）资助。

Channel modeling and simulation of high-frequency magnetic coupling wired drill pipe

Hu Yongjian, Huang Yanfu, Shi Lin

CNPC Drilling Research Institute, Beijing 102206, China

Received:2017-12-11 Revised:2018-08-24 Online:2018-11-25 Published:2018-12-10

摘要/Abstract

摘要：

高频磁耦合有缆钻杆能够提高随钻测量数据的传输速率，其使用同轴电缆减少信道的高频损耗，利用磁耦合感应实现钻杆之间的无线信号传输。为了确定信号载波频率、实现不同有缆钻具间的阻抗匹配以及降低信道衰减，使用2种不同模型完成了信道建模与仿真分析。首先使用标准二端口网络元件级联模型仿真，虽然基于测量数据的"黑箱"网络元件无法给出物理解释，也没有用于优化的设计参数，但仿真结果有利于有缆钻杆工艺改进的验证性实验。其次使用集总参数电路和传输线混合模型仿真，其中集总参数电路有可测量的设计参数，在提供物理解释的同时能够优化设计，而传输线仿真了高频条件下长度不能忽略的同轴电缆。混合模型使用分级网络的链接参数完成散射参数的计算，设定了耦合系数、绕组电感及磁滞损耗3个调谐参数，仿真结果与测量结果相吻合。

关键词: 磁耦合, 有缆钻杆, 信道建模, 二端口网络, 混合模型, 集总参数电路, 传输线

Abstract:

High-frequency magnetic coupling wired drill pipe can increase the transmission rate of MWD (measurement-while-drilling)data, able to use coaxial cable for reducing high-frequency loss and realize wireless signal transmission between drill rods based on magnetic coupling effect. To determine the signal-carrier frequency, achieve the matching impedance between different wired drilling tools and reduce channel attenuation, two different models are utilized to complete the channel modeling and simulation analysis. Firstly, the cascade model of standard two-port network elements is used for simulation. Although the "black box" network element based on measurement data is unable to give physical explanation, and also cannot provide optimized design parameters, the simulation results are beneficial to the verification experiment of wired drill pipe process. Secondly, the hybrid model combining lumped-parameter circuit and transmission line is applied for simulation; the lumped-parameter circuit has measurable design parameters, able to provide physical explanation and optimize the system, and the transmission line simulates the coaxial cable with the length unable to be ignored under high-frequency conditions. In the hybrid model, the scattering parameter is calculated by the link parameters of cascade network, so as to set three tuning parameters (coupling coefficient, winding inductance and hysteresis loss). The simulation results are exactly consistent with those measured data.

Key words: magnetic coupling, wired drill pipe, channel modeling, two-port network, hybrid model, lumped-parameter circuit, transmission line

中图分类号:

TE271

胡永建, 黄衍福, 石林. 高频磁耦合有缆钻杆信道建模与仿真分析[J]. 石油学报, 2018, 39(11): 1292-1298,1316.

Hu Yongjian, Huang Yanfu, Shi Lin. Channel modeling and simulation of high-frequency magnetic coupling wired drill pipe[J]. Acta Petrolei Sinica, 2018, 39(11): 1292-1298,1316.

参考文献

[1] 郑宏远,白锐,刘策.石油钻井泥浆脉冲发生器数据传输速率分析[J].计算机仿真,2016,33(7):194-199.
ZHENG Hongyuan,BAI Rui,LIU Ce.Numerical analysis of the data transmission rate of a mud pulse data communication system[J].Computer Simulation,2016,33(7):194-199.
[2] 范业活,李天禄,杨志强.随钻无线传输技术分析与比较[J].测井技术,2016,40(4):455-459.
FAN Yehuo,LI Tianlu,YANG Zhiqiang.Analysis and comparison of MWD transmission technology[J].Well Logging Technology,2016,40(4):455-459.
[3] 房涛,张立宽,刘乃贵,等.核磁共振技术定量表征致密砂岩气储层孔隙结构——以临清坳陷东部石炭系-二叠系致密砂岩储层为例[J].石油学报,2017,38(8):902-915.
FANG Tao,ZHANG Likuan,LIU Naigui,et al.Q uantitative characterization of pore structure of tight gas sandstone reservoirs by NMR T2 spectrum technology:a case study of Carboniferous-Permian tight sandstone reservoir in Linqing depression[J].Acta Petrolei Sinica,2017,38(8):902-915.
[4] 刘标,姚素平,胡文瑄,等.核磁共振冻融法表征非常规油气储层孔隙的适用性[J].石油学报,2017,38(12):1401-1410.
LIU Biao,YAO Suping,HU Wenxuan,et al.Application of nuclear magnetic resonance cryoporometry in unconventional reservoir rocks[J].Acta Petrolei Sinica,2017,38(12):1401-1410.
[5] 代全齐,罗群,张晨,等.基于核磁共振新参数的致密油砂岩储层孔隙结构特征——以鄂尔多斯盆地延长组7段为例[J].石油学报,2016,37(7):887-897.
DAI Quanqi,LUO Qun,ZHANG Chen,et al.Pore structure characteristics of tight-oil sandstone reservoir based on a new parameter measured by NMR experiment:a case study of seventh Member in Yanchang Formation,Ordos Basin[J].Acta Petrolei Sinica,2016,37(7):887-897.
[6] 白松涛,程道解,万金彬,等.砂岩岩石核磁共振T2谱定量表征[J].石油学报,2016,37(3):382-391.
BAI Songtao,CHENG Daojie,WAN Jinbin,et al.Q uantitative characterization of sandstone NMR T2 spectrum[J].Acta Petrolei Sinica,2016,37(3):382-391.
[7] 徐宝昌,孟宇,刘伟.控压钻井井下不可测变量的非线性估计[J].石油学报,2016,37(12):1543-1549.
XU Baochang,MENG Yu,LIU Wei.Nonlinear estimation of the down-hole unmeasurable variables in the managed pressure drilling system[J].Acta Petrolei Sinica,2016,37(12):1543-1549.
[8] NOV Wellbore Technologies.eVolve Optimization Service:INFORM (NOV-DDS-F-1358-001)[EB/OL].(2017)[2018-09-01]. http://www.nov.com/WorkArea/DownloadAsset.aspx?id=28803.
[9] NOV Wellbore Technologies.eVolve Optimization Service:ADVISE (NOV-DDS-F-1359-001)[EB/OL].(2015)[2018-09-01]. http://www.nov.com/WorkArea/DownloadAsset.aspx?id=19273.
[10] NOV Wellbore Technologies.eVolve Optimization Service:CONTROL (NOV-DDS-F-1360-001)[EB/OL].(2015)[2018-09-01]. http://www.nov.com/WorkArea/DownloadAsset.aspx?id=19274.
[11] NOV Wellbore Technologies.eVolve Optimization Service:AUTOMATE (NOV-DDS-F-1396-001)[EB/OL].(2015)[2018-09-01]. http://www.nov.com/WorkArea/DownloadAsset.aspx?id=19275.
[12] NOV Wellbore Technologies.IntelliServ Product Catalog (D392004875-MKT-001 Rev.03)[EB/OL].[2018-09-01]. http://www.nov.com/WorkArea/DownloadAsset.aspx?id=25816.
[13] CARPENTER C.Wired-drillpipe technology in a deep ultradepleted reservoir[J].Journal of Petroleum Technology,2014,66(6):101-103.
[14] FOSSE M.Wired drill pipe technology:technical and economic overview[D]. Stavanger,Norway:University of Stavanger,2015:6.
[15] 荣继光,熊继有,余荣华,等.智能钻杆导电环结构有限元分析[J].西南石油大学学报:自然科学版,2013,35(1):168-172.
RONG Jiguang,XIONG Jiyou,YU Ronghua,et al.Finite element analysis of conducting ring structure of the intelligent drill pipe[J].Journal of Southwest Petroleum University:Science & Technology Edition,2013,35(1):168-172.
[16] 孙浩玉.智能钻杆磁感应传输技术及其信道特性分析[J].中国石油大学学报:自然科学版,2013,37(6):172-176.
SUN Haoyu.Technology of magnetic induction transmission of intelligent drill pipe and its channel characteristics[J].Journal of China University of Petroleum:Edition of Natural Science,2013,37(6):172-176.
[17] 刘亚军,孙东奎,刘锋,等.甚低频磁感应波智能钻杆信号传输系统性能分析[J].西安石油大学学报:自然科学版,2017,32(1):119-126.
LIU Yajun,SUN Dongkui,LIU Feng,et al.Performance analysis of intelligent measurement system while drilling based on the magneto-inductive wave of very low frequency[J].Journal of Xi'an Shiyou University:Natural Science Edition,2017,32(1):119-126.
[18] 高奇峰,杨兆建,何吉利.分离式变压器电磁结构与参数分析[J].电力自动化设备,2009,29(9):141-144.
GAO Qifeng,YANG Zhaojian,HE Jili.Electromagnetic structure and parameter analysis of separated transformer[J].Electric Power Automation Equipment,2009,29(9):141-144.
[19] 张献,杨庆新,陈海燕,等.电磁耦合谐振式无线电能传输系统的建模、设计与实验验证[J].中国电机工程学报,2012,32(21):153-158.
ZHANG Xian,YANG Qingxin,CHEN Haiyan,et al.Modeling and design and experimental verification of contactless power transmission systems via electromagnetic resonant coupling[J].Proceedings of the CSEE,2012,32(21):153-158.
[20] 疏许健,张波.感应耦合无线电能传输系统的能量法模型及特性分析[J].电力系统自动化,2017,41(2):28-32.
SHU Xujian,ZHANG Bo.Energy model and characteristic analysis for inductively coupled power transfer system[J].Automation of Electric Power Systems,2017,41(2):28-32.
[21] 李艳红,刘国强,宋显锦,等.宽频磁耦合谐振式无线电能传输系统特性分析[J].电工技术学报,2015,30(19):7-11.
LI Yanhong,LIU Guoqiang,SONG Xianjin,et al.The study on the characteristics of broadband magnetic coupling resonant wireless power transfer system[J].Transactions of China Electrotechnical Society,2015,30(19):7-11.
[22] 黄学良,王维,谭林林.磁耦合谐振式无线电能传输技术研究动态与应用展望[J].电力系统自动化,2017,41(2):2-14.
HUANG Xueliang,WANG Wei,TAN Linlin.Technical progress and application development of magnetic coupling resonant wireless power transfer[J].Automation of Electric Power Systems,2017,41(2):2-14.
[23] 胡永建,黄衍福,孙成芹,等.一种有缆钻杆信道参数的测量方法及系统:中国,CN201510983400.3[P].2016-05-25.
HU Yongjian,HUANG Yanfu,SUN Chengqin,et al.Cable drill rod channel parameter measuring method and system:CN,201510983400.3[P].2016-05-25.
[24] RADMANESH M M.射频与微波电子学[M].顾继慧,李鸣译.北京:电子工业出版社,2012.
RADMANESH M M.Radio frequency and microwave electronics illustrated[M].Translated by GU Jihui,LI Ming.Beijing:Publishing House of Electronic Industry,2012.
[25] LEE T H.平面微波工程:理论、测量与电路[M].余志平,孙玲玲,王皇译.北京:清华大学出版社,2014.
LEE T H.A practical guide to theory,measurements and circuits[M].Translated by YU Zhiping,SUN Lingling,WANG Huang.Beijing:Tsinghua University Press,2014.
[26] 董纪清,陈为,卢增艺.开关电源高频变压器电容效应建模与分析[J].中国电机工程学报,2007,27(31):121-126.
DONG Jiqing,CHEN Wei,LU Zengyi.Modeling and analysis of capacitive effects in high-frequency transformer of SMPS[J].Proceedings of the CSEE,2007,27(31):121-126.

高频磁耦合有缆钻杆信道建模与仿真分析

Channel modeling and simulation of high-frequency magnetic coupling wired drill pipe

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