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山东大学学报(工学版) ›› 2015, Vol. 45 ›› Issue (6): 99-106.doi: 10.6040/j.issn.1672-3961.0.2014.259

• 其他 • 上一篇    

方位电阻率测井在地层界面电磁响应的研究

高杨, 孔凡敏, 李康   

  1. 山东大学信息科学与工程学院, 山东济南 250100
  • 收稿日期:2014-09-16 修回日期:2015-06-02 出版日期:2015-12-20 发布日期:2014-09-16
  • 通讯作者: 孔凡敏(1969-),男,山东泗水人,教授,博士,主要研究方向为计算电磁学.E-mail:fanminkong@163.com E-mail:fanminkong@163.com
  • 作者简介:高杨(1990-),男,辽宁阜新人,硕士研究生,主要研究方向为电磁测井.E-mail:gy10200515shx@163.com
  • 基金资助:
    国家自然科学基金资助项目(61475084)

Research on the electromagnetic responses of azimuthal resistivity logging in formation boundaries

GAO Yang, KONG Fanmin, LI Kang   

  1. School of Information Science and Engineering, Shandong University, Jinan 250100, Shandong, China
  • Received:2014-09-16 Revised:2015-06-02 Online:2015-12-20 Published:2014-09-16

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摘要: 利用解析法计算随钻方位电阻率仪器激发的电磁场随仪器方位变化的规律,研究其在地层界面预测中的应用。通过分析电磁波在各层介质中的反射和透射规律,得出了介质层中电磁波的解析表达式,计算了电磁波电阻率随钻测量的幅度衰减和相移,分析了定向电磁测量对地层界面的灵敏性,研究了地层相对倾角和接收天线倾角对电磁测量的影响。研究表明,线圈距和目的层厚度越大,定向电磁测量的探测范围越大;随着地层相对倾角和接收天线倾角的增加,定向幅度衰减在接近地层界面时的变化越明显,对地层界面的灵敏性增强。结合方位电阻率成像和定向电磁响应说明,在常规随钻电阻率仪器的基础上,增加倾斜接收天线,可以实现地层倾向的预测和判断。

关键词: 磁偶极子, 定向相移, 方位电阻率, 定向幅度衰减, 地层界面, 倾斜天线

Abstract: The electromagnetic field of different azimuth was calculated by analytical method, and then its application for forecasting formation boundaries was researched. By studying the reflection and transmission of electromagnetic wave on each layer, an analytic expression for electromagnetic wave was obtained, which satisfied boundary condition of each layer, and then the amplitude-attenuation and phase-shift of electromagnetic wave resistivity logging were computed. The sensitivity to formation boundaries of directional electromagnetic measurements was analyzed, and the influence of formation relative dip angle and receiver antenna dip angle on directional measurements was also studied. The results showed that the directional detection range increased with the coil spacing and the thickness of target bed increasing. The change of directional amplitude-attenuation became more obvious with the formation relative dip angle and receiver antenna dip angle increasing when the tool was approaching formation boundary, and thus the sensitivity to formation boundaries increased. By combining azimuthal resistivity image with directional electromagnetic response, the results showed that adding tilt antenna to conventional logging while drilling resistivity tools, the formation boundaries could be accurately forecasted.

Key words: azimuthal resistivity, tilted antenna, formation boundary, directional amplitude attenuation, magnetic dipole, directional phase shift

中图分类号: 

  • P631.811
[1] RODNEY P F, WISLER M M. Electromagnetic wave resistivity MWD tool[J]. SPE Drilling Engineering, 1986, 1(5):337-346.
[2] BITTAR M S, RODNEY P F, MACK S G, et al. A multiple depth of investigation electromagnetic wave resistivity sensor:theory, experiment, and field test results[J]. SPE Formation Evaluation, 1993, 8(3):171-176.
[3] MEYER W H. New two frequency propagation resistivity tools[C]//SPWLA 36th Annual Logging Symposium. Paris, France:Society of Petrophysicists and Well Logging Analysts, 1995:1-8.
[4] BITTAR M S, RODNEY P E. The effects of rock anisotropy on MWD electromagnetic wave resistivity sensors[J]. The Log Analyst, 1996, 37(1):20-30.
[5] BITTAR M S. Fixed depth of investigation log for LWD resistivity tool[C]//SPE Annual Technical Conference and Exhibition, Transactions, SPE 84098. Denver, USA:Society of Petroleum Engineers, 2003:1-10.
[6] IVERSON M. Geosteering using ultra-deep resistivity on the Grane field Norwegian North Sea[C]//SPWLA 44th Annual Logging Symposium. Galveston, USA:Society of Petrophysicists and Well Logging Analysts, 2003:30-38.
[7] BITTAR M S. Electromagnetic wave resistivity tool having a tilted antena for determining the horizontal and vertical resistivities and relative dip angle in anisotropic earth formations[P]. US Patent:6163155, 2000:1-14.
[8] BITTAR M S. Electromagnetic wave resistivity tool having a tilted antenna for geosteering within a desired payzone[P]. US Patent:6476609, 2002:1-11.
[9] 杨锦舟,魏宝君,林楠.倾斜线圈随钻电磁波电阻率测量仪器基本原理及其在地质导向中的应用[J]. 中国石油大学学报:自然科学版, 2009, 33(1):44-49. YANG Jinzhou, WEI Baojun, LIN Nan. Basic theory of electromagnetic wave reisitivity measurement while drilling tool with tilted antennas and its application for geosteering[J]. Journal of China University of Petroleum:Natural Science Edition, 2009, 33(1):44-49.
[10] KENNEDY W D, CORLEY B, PAINCHAUD S, et al. Geosteering using deep resistivity images from azimuthal and multiple propagation resistivity[C]//SPWLA 50th Annual Logging Symposium. Houston, USA:Society of Petrophysicists and Well Logging Analysts, 2009:1-16.
[11] ZHANG Z Y, GONGUET C, RAIAN V, et al. Directional LWD resistivity tools and their business impacts[C]//SPWLA 49th Annual Logging Symposium. Houston, USA:Society of Petrophysicists and Well Logging Analysts, 2008:1-16.
[12] BITTAR M, ALTHOFF G, BESTE R, et al. Field testing of a new LWD triaxial sensor for anisotropy and dip measurement in vertical and deviated wells[C]//SPWLA 52nd Annual Logging Symposium. Houston, USA:Society of Petrophysicists and Well Logging Analysts, 2011:1-15.
[13] BELL C, HAMPSON J, EADSFORTH P. Navigating and imaging in complex geology with azimuthal propagation resistivity while drilling[C]//SPE Annual Technical Conference and Exhibition Transactions. Dallas, USA:Society of Petroleum Engineers, 2006:1-14.
[14] WANG T. Method of generating a deep resistivity image in LWD measurments[P]. US Patent:7483793B2, 2009:1-17.
[15] FANG S. Resolution analysis of azimuthal directional resistivity images[C]//Offshore Technology Conference Brasil, OTC 22310. Rio de Janeiro, Brasil:[s.n], 2011:1-12.
[16] BITTAR M, KLEIN J, BESTE R, et al. A new azimuthal deep-reading resistivity tool for geosteering and advanced formation evaluation[C]//SPE Annual Technical Conference and Exhibition, Transactions, SPE Paper 109971. Anaheim, USA:Society of Petroleum Engineers, 2007:270-279.
[17] CHEN W C. Waves and fields in inhomeneous media[M]. New York, US:Van Nostrand Reinhold, 1990.
[18] 其木苏荣,赵永芳,井孝功.偶极子在径向非均匀介质中的电磁场分布[J]. 大学物理,2004, 23(8):16-19. QIMUSURONG, ZHAO Yongfang, JING Xiaogong. The electromagnetic field of MD in radial inhomogeneous medium[J]. College Physics, 2004, 23(8):16-19.
[19] 其木苏荣,刘凤敏,井孝功,等.水平层状介质中任意方向磁偶极子的电磁场分布[J].大学物理, 2006, 25(10):31-37. QIMUSURONG, LIU Fengmin, JING Xiaogong, et al. Electromagnetic field of a free oriented MD in inhomogeneous media[J]. College Physics, 2006, 25(10):31-37.
[20] 胡启,许杰.感应测井理论[M].西安:陕西人民教育出版社, 1985.
[21] 魏宝君,田坤,张旭,等.定向电磁波传播随钻测量基本理论及其在地层界面预测中的应用[J]. 地球物理学报, 2010, 53(10):2507-2515. WEI BaoJun, TIAN Kun, ZHANG Xu, et al. Physics of directional electromagnetic propagation measurements-while-drilling and its application for forecasting formation boundaries[J]. Chinese Journal of Geophysics, 2010, 53(10):2507-2515.
[22] LI Q M, OMERAGIC D, CHOU L, et al. New directional electromagnetic tool for proactive geosteering and accurate formation evaluation while drilling[C]//SPWLA 46th Annual Symposium. New Orleans, USA:Society of Petrophysicists and Well Log Analysts, 2005:1-16.
[23] 杨震,杨锦舟,韩来聚. 随钻方位电磁波电阻率成像模拟及应用[J]. 吉林大学学报:地球科学版, 2013, 43(6):2035-2043. YANG Zhen, YANG Jinzhou, HAN Laiju. Numerical simulation and application of azimuthal propagation resistivity imaging while drilling[J]. Journal of Jilin University:Earth Science Edition, 2013, 43(6):2035-2043.
[24] CHEMALI R, HART E, FLYNN T, et al. Successful application of azimuthal propagation resistivity for optimum well placement and reservoir characterization while drilling[C]//SPE Annual Technical Conference and Exhibition, SPE 109959. Anaheim, USA:Society of Petroleum Engineers, 2007:1-12.
[25] PITCHER J, BITTAR M, HINZ D, et al. Interpreting azimuthal propagation resistivity:a paradigm shift[C]//SPE EUROPEC/EAGE Annual Technical Conference and Exhibition, SPE 143303. Vienna, Austria:Society of Petroleum Engineers, 2011:1-16.
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