天然气水合物储层测井评价及其影响因素

doi:10.7623/syxb201303026

石油学报 ›› 2013, Vol. 34 ›› Issue (3): 591-606.DOI: 10.7623/syxb201303026

天然气水合物储层测井评价及其影响因素

宁伏龙¹, 刘力¹, 李实², 张可², 蒋国盛¹, 吴能友³, 孙长宇⁴, 陈光进⁴

1. 中国地质大学工程学院武汉 430074;
2. 中国石油勘探开发研究院提高石油采收率国家重点实验室北京 100083;
3. 中国科学院广州天然气水合物研究中心广州 510640;
4. 中国石油大学化学工程学院北京 102249

收稿日期:2012-11-26 修回日期:2013-03-28 出版日期:2013-05-25 发布日期:2013-04-09
通讯作者: 宁伏龙
作者简介:宁伏龙,男,1977 年8月生,2000年获中国地质大学(武汉)学士学位,2005年获中国地质大学(武汉)博士学位,现为中国地质大学(武汉)教授,主要从事天然气水合物勘探与开发、海洋钻探研究工作。Email:nflzx@cug.edu.cn
基金资助:
国家自然科学基金项目(No.40974071,No.51274177)、教育部霍英东基金(132019)、提高石油采收率国家重点实验室项目(2011A-1002)和中国地质大学(武汉)学校项目(CUGL100410,CUG120112)资助。

Well logging assessment of natural gas hydrate reservoirs and relevant influential factors

NING Fulong¹, LIU Li¹, LI Shi², ZHANG Ke², JIANG Guosheng¹, WU Nengyou³, SUN Changyu⁴, CHEN Guangjin⁴

1. Faculty of Engineering, China University of Geosciences, Wuhan 430074, China;
2. State Key Laboratory of Enhanced Oil Recovery, PetroChina Research Institute of Petroleum Exploration & Development, Beijing 100083, China;
3. Guangzhou Centre for Gas Hydrate Research, CAS, Guangzhou 510640, China;
4. Faculty of Chemical Engineering, China University of Petroleum, Beijing 102249, China

Received:2012-11-26 Revised:2013-03-28 Online:2013-05-25 Published:2013-04-09

摘要/Abstract

摘要：

天然气水合物储层准确识别和精细定量评价是自然界水合物开发利用和环境影响研究的基础,而地球物理测井则是除地震和钻探取心外最有效的原位识别和评价方法。电阻率和声波测井是最早应用于水合物储层识别的井内地球物理方法,由于具有较高的准确性和可靠性,二者仍是目前水合物测井的主要方式,并不断衍生出新的技术,如环电阻率、方向电阻率、多极声波测井等;同时,其他如井内成像、密度、电磁波、核磁共振等测井方法也被综合用于识别水合物储层。经过最近20年的发展,水合物系统测井方法已从单一的测井识别发展到运用各种先进的随钻和电缆测井评价复杂地质条件下水合物储层物性的阶段,初步建立了一套基于常规油气系统的水合物系统测井评价理论体系。该套体系对均质孔隙填充型砂质水合物储层具有较好的适用性,但对于非均质性泥质储层(如裂隙、薄层、互层、富泥质)及胶结或骨架支撑形式的水合物储层应用会产生较大的误差。此外,钻井过程中井眼冲蚀和钻井液侵入等外部因素也会影响水合物测井识别和评价结果。通过了解不同测井方法及其最新的研究进展,认为未来水合物测井技术的发展应侧重提高水合物地层识别和评价的准确性,开发复杂条件下水合物储层岩石物理模型,并综合利用地震、测井、岩心分析等方法修正所建立的岩石物理模型和校正实际的测井结果。

关键词: 天然气水合物, 储层, 测井, 评价方法, 影响因素, 准确性

Abstract:

The accurate identification and quantitative assessment of natural gas hydrate reservoirs are thought to be a base for development and utilization of gas hydrates and study of environmental impact. Besides seismic prospecting and core drilling, geophysical well logging is one of the most effective method of identification and evaluation to understand the nature of hydrate reservoirs. Resistivity and acoustic logging as the earliest applied geophysical methods in the identification of hydrate reservoirs are still ways for hydrate well logging due to their relatively good accuracy and reliability and therefore derive some new well logging methods such as ring resistivity, directional resistivity, multiple acoustic logging, etc. Other logging methods including borehole imaging, density, electromagnetic wave, nuclear magnetic resonance, etc. are also used together with resistivity and sonic logging to make an integrated interpretation and evaluation of hydrate reservoirs. With development of the past decades, well logging method of hydrate systems has finished a process from using single logging to adopting wireline and advanced logging-while-drilling tools to evaluate the petrophysical nature of gas hydrate reservoirs under complex geological conditions, and a preliminary theory and technology system based on conventional petrophysical models has been established. This system is generally suitable for homogeneous hydrate reservoirs, but not for heterogeneous argillaceous hydrate reservoirs (e.g. fracture, thin layer, interbed, shale-rich sediment, etc.). In addition, some external factors, such as wellbore washout and invasion of drilling fluid will also affect results of well logging. The present paper reviews the latest research progress in different well logging methods, and suggests that in the near future, new petrophysical models for identification and evaluation of complicated heterogeneous hydrate reservoirs as well as calibration methods for compensating defect caused by wellbore washout and invasion of drilling fluid in well logging will be set up or adopted to enhance accuracy of well logging in identification and evaluation of hydrate reservoirs.

Key words: gas hydrate, reservoir, well logging, evaluation method, influential factor, accuracy

中图分类号:

TE631.84

宁伏龙, 刘力, 李实, 张可, 蒋国盛, 吴能友, 孙长宇, 陈光进. 天然气水合物储层测井评价及其影响因素[J]. 石油学报, 2013, 34(3): 591-606.

NING Fulong, LIU Li, LI Shi, ZHANG Ke, JIANG Guosheng, WU Nengyou, SUN Changyu, CHEN Guangjin. Well logging assessment of natural gas hydrate reservoirs and relevant influential factors[J]. Editorial office of ACTA PETROLEI SINICA, 2013, 34(3): 591-606.

参考文献

[1] National Research Council of the National Academies.Realizing the energy potential of methane hydrate for the United States[M].Washington DC:National Academies Press,2010.

[2] Collett T S,Lewis R,Winters W J,et al.Downhole well log and core montages from the Mount Elbert gas hydrate stratigraphic test well,Alaska North Slope[J].Marine and Petroleum Geology,2011,28(2):561-577.

[3] Collett T S,Lee M W.Downhole well log characterization of gas hydrates in nature-a review[R].Edinburgh:ICGH,2011.

[4] Lee M W,Collett T S.Gas hydrate saturations estimated from fractured reservoir at site NGHP-01-10,Krishna-Godavari Basin,India[J].Journal of Geophysical Research,2009,114(B7):1-13.

[5] 陆敬安,闫桂京.天然气水合物测井与评价技术进展[J].海洋地质动态,2007,23(6):31-36.

Lu Jing’an,Yan Guijing.Advance in well logging and evaluation techniques of gas hydrates[J].Marine Geology Letters,2007,23(6):31-36.

[6] 高兴军,于兴河,李胜利,等.地球物理测井在天然气水合物勘探中的应用[J].地球科学进展,2003,18(2):305-311.

Gao Xingjun,Yu Xinghe,Li Shengli,et al.Application of geophysical well logging technology in exploration of gas hydrate[J].Advance in Earth Sciences,2003,18(2):305-311.

[7] 王祝文,李舟波,刘菁华.天然气水合物的测井识别和评价[J].海洋地质与第四纪地质,2003,23(2):97-102.

Wang Zhuwen,Li Zhoubo,Liu Jinghua.Logging identification and evaluation methods for gas hydrate[J].Marine Geology & Quaternary Geology,2003,23(2):97-102.

[8] Collett T S.Detection and evaluation of the in-situ natural gas hydrates in the North Slope Region,Alaska[R].SPE11673,1983.

[9] Cook A E,Anderson B I,Rasmus J,et al.Electrical anisotropy of gas hydrate-bearing sand reservoirs in the Gulf of Mexico[J].Marine and Petroleum Geology,2012,34(1):72-84.

[10] Jin Y K,Lee M W,Collett T S.Relationship of gas hydrate concentration to porosity and reflection amplitude in a research well,Mackenzie Delta,Canada[J].Marine and Petroleum Geology,2002,19(4):407-415.

[11] Lee M W,Collett T S.Pore-and fracture-filling gas hydrate reservoirs in the Gulf of Mexico Gas Hydrate Joint Industry Project Leg II Green Canyon 955 H well[J].Marine and Petroleum Geology,2012,34(1):62-71.

[12] Stoll R D,Bryan G M.Physical properties of sediments containing gas hydrates[J].Journal of Geophysical Research,1979,84(B4):1629-1634.

[13] Zimmerman R W,King M S.The effect of the extent of freezing on seismic velocities in unconsolidated permafrost[J].Geophysics,1986,51(6):1285-1290.

[14] Pearson C,Murphy J,Halleck P,et al.Sonic and resistivity measurements on Berea sandstone containing tetrahydrofuran hydrates:a possible analog to natural gas hydrate deposits[R].Fairbanks:Fourth International Conference on Permafrost,1983.

[15] Winters W J,Waite W F,Mason D H,et al.Methane gas hydrate effect on sediment acoustic and strength properties[J].Journal of Petroleum Science and Engineering,2007,56(1/2/3):127-135.

[16] Pearson C,Halleck P,McGuire P,et al.Natural gas hydrate deposits:a review of in situ properties[J].The Journal of Physical Chemistry,1983,87(21):4180-4185.

[17] Tréhu A M,Rack F R,Chapman M, et al.Drilling gas hydrates on hydrate ridge,cascadia continental Margin[R].ODPLeg 204 Preliminary Report,2002..

[18] 陆敬安,杨胜雄,吴能友,等.南海神狐海域天然气水合物地球物理测井评价[J].现代地质,2008,22(3):447-451.

Lu Jing’an,Yang Shengxiong,Wu Nengyou,et al.Well logging evaluation of gas hydrates in Shenhu area,South China Sea[J].Geoscience,2008,22(3):447-451.

[19] Guerin G,Cook A,Mrozewski S,et al.Gulf of Mexico gas hydrate joint industry project leg II:Green Canyon 955 LWD operations and results[R].Houston:Proceedings of the Drilling and Scientific Results of the 2009 Gulf of Mexico Gas Hydrate Joint Industry Project Leg II,2009.

[20] Sun Y F,Goldberg D.Analysis of electromagnetic propagation tool response in gas-hydrate-bearing formations[R].Ottawa:Geological Survey of Canada,2005.

[21] Worthington P F.Petrophysical evaluation of gas-hydrate formations[J].Petroleum Geoscience,2010,16(1):53-66.

[22] Mathews M.Logging characteristics of methane hydrate[J].The Log Analyst,1986,27(3):26-63.

[23] Collett T S,Lewis R E,Dallimore S R.Mallik 5L-38 gas hydrate production research well downhole well-log and core montages[R].Ottawa:Geological Survey of Canada,2005.

[24] Collett T S,Lee M W,Zyrianova M V,et al.Gulf of Mexico Gas Hydrate Joint Industry Project Leg II logging-while-drilling data acquisition and analysis[J].Marine and Petroleum Geology,2012,34(1):41-61.

[25] Lee M W,Collett T S.Integrated analysis of well logs and seismic data to estimate gas hydrate concentrations at Keathley Canyon,Gulf of Mexico[J].Marine and Petroleum Geology,2008,25(9):924-931.

[26] Inks T L,Collett T,Taylor D J,et al.Prospecting for gas hydrate accumulations using 2D and 3D seismic data,Milne Point,North Slope Alaska:AAPG Hedberg Conference "Gas Hydrate:Energy Resource Potential and Associated Geologic Hazards",September 12-16,2004[C].Vancouver:AAPG,2004.

[27] Lee M W,Collett T S.In-situ gas hydrate hydrate saturation estimated from various well logs at the Mount Elbert Gas Hydrate Stratigraphic Test Well,Alaska North Slope[J].Marine and Petroleum Geology,2011,28(2):439-449.

[28] Li Fengguang,Sun Changyu,Li Shengli,et al.Experimental studies on the evolvement of electrical resistivity during methane hydrate formation in sediments[J].Energy & Fuels,2012,26(10):6210-6217.

[29] Fofonoff N P.Physical properties of seawater:a new salinity scale and equation of state for seawater[J].Journal of Geophysical Research,1985,90 (C2):3332-3342.

[30] Arps J J.The effect of temperature on the density and electrical resistivity of sodium chloride solutions[J].Jouranl of Petroleum Technology,1953,5(10):17-20.

[31] Wood A.B.A Textbook of Sound[M].London:Bell and Sons,Ltd,1955.

[32] Lee M W,Collett T S.Amount of gas hydrate estimated from compressional and shear-wave velocities at the JAPEX/JNOC/GSC Mallik 2L-38 gas hydrate research well[R].Ottawa:Geological Survey of Canada,1999.

[33] Helgerud M B,Dvorkin J,Nur A,et al.Elastic-wave velocity in marine sediments with gas hydrates:effective medium modeling[J].Geophysical Research Letters,1999,26(13):2021-2024.

[34] Lee M W.Biot-Gassmann theory for velocities of gas hydrate-bearing sediments[J].Geophysics,2002,67(6):1711-1719.

[35] Carcione J M,Tinivella U.Bottom-simulating reflectors:seismic velocities and AVO effects[J].Geophysics,2000,65(1):54-67.

[36] Lee M W,Hutchinson D R,Collett T S,et al.Seismic velocities for hydrate-bearing sediments using weighted equation[J].Journal of Geophysical Research,1996,101(B9):20347-20358.

[37] Lee M W.Gas hydrates amount estimated from acoustic logs at the Blake Ridge,sites 994,995,and 997[R].Texas:Proceedings of the Ocean Drilling Program,2000:193-198.

[38] Helgerud M B,Dvorkin J,Nur A.Rock physics characterization for gas hydrate reservoirs:elastic properties[J].Annals of the New York Academy of Sciences,2000,912:116-125.

[39] Murray D R,Fukuhara M,Osawa O,et al.Saturation,acoustic properties,growth habit,and state of stress of a gas hydrate reservoir from well logs[J].Petrophysics,2006,47(2):129-137.

[40] Lee M W.Models for gas hydrate-bearing sediments inferred from hydraulic permeability and elastic velocities[R].USGS,2008.

[41] Lee M W,Waite W F.Estimating pore-space gas hydrate saturations from well log acoustic data[J].Geochemistry,Geophysics,Geosystems,2008,9(7):1-8.

[42] Hill R.The elastic behavior of crystalline aggregates[J].Proceedings of the Physical Society,1952,A65:349-354.

[43] Sun Y,Goldberg D,Collett T,et al.High-resolution well-log derived dielectric properties of gas-hydrate-bearing sediments,Mount Elbert Gas Hydrate Stratigraphic Test Well,Alaska North Slope[J].Marine and Petroleum Geology,2011,28(2):450-459.

[44] Wright J F,Nixon F M,Dallimore S R,et al.A method for direct measurement of gas hydrate amounts based on the bulk dielectric properties of laboratory test media[R].Yokohama:Fourth International Conference on Gas Hydrates,2002.

[45] Paull C,Matsumoto R,Wallace P,et al.Gas hydrate sampling on the Blake Ridge and Carolina Rise[R].Texas:proceedings of the Ocean Drilling Program,1996.

[46] Riedel M,Collett T,Malone M,et al.Cascadia Margin Gas Hydrates,Expedition 311,Sites U1325-U1329[R].Washingtong DC:Proceedings of the Integrated Ocean Drilling Program,2006.

[47] Tsuji Y,Ishida H,Nakamizu M,et al.Overview of the MITI Nankai Trough Wells:a milestone in the evaluation of methane hydrate resources[J].Resource Geology,2004,54(1):3-10.

[48] Ruppel C,Boswell R,Jones E.Scientific results from Gulf of Mexico Gas Hydrates Joint Industry Project Leg II drilling:introduction and overview[J].Marine and Petroleum Geology,2008,25(9):819-829.

[49] Boswell R,Collett T,Frye M,et al.Gulf of Mexico Gas Hydrate Joint Industry Project Leg II:technical summary[R].Houston:Proceedings of the drilling and scientific results of the 2009 Gulf of Mexico Gas Hydrate Joint Industry Project Leg II,2009.

[50] Collett T,Riedel M,Cochran J,et al.Indian national gas hydrate program expedition 01 initial reports[R].India:Ministry of Petroleum and Natural Gas,2008.

[51] Park K P.Gas hydrate exploration activities in Korea,Proceedings of the 6th International Conference on Gas Hydrates,Vancouver,July 6—10,2008[C].Vancouver:ICGH,2008.

[52] Gas Hydrate R&D Organization,Korea.Second Ulleung basin gas hydrate expedition (UBGH2)[J].Fire In the Ice,2010,10(1):18.

[53] Wu N,Yang S,Zhang H.Preliminary discussion on gas hydrate reservoir system of Shenhu Area,North Slope of South China Sea,Proceedings of the 6th International Conference on Gas Hydrates,Vancouver,July 6—10,2008[C].Vancouver:ICGH,2008.

[54] Collett T S,Ginsburg G D.Gas hydrates in the Messoyakha gas field of the West Siberian Basin—a re-examination of the geologic evidence[J].International Journal of Offshore and Polar Engineering,1998,8(1):22-29.

[55] Geological Survey of Canda.Scientific results from the Mallik 2002 gas hydrate production research well program,Mackenzie Delta,Northwest Territories,Canada[R].Ottawa:Geological Survey of Canada,2005.

[56] Hunter R B,Collett T S,Boswell R,et al.Mount Elbert Gas Hydrate Stratigraphic Test Well,Alaska North Slope:Overview of scientific and technical program[J].Marine and Petroleum Geology,2011,28(2):295-310.

[57] Lu Z,Zhu Y,Zhang Y,et al.Gas hydrate occurrences in the Qilian Mountain permafrost,Qinghai Province,China[J].Cold Regions Science and Technology,2011,66(2):93-104.

[58] Anderson B I,Collett T S,Lewis R E,et al.Using open hole and cased-hole resistivity logs to monitor gas hydrate dissociation during a thermal test in the Mallik 5L-38 research Well,Mackenzie Delta,Canada[J].Petrophysics,2008,49(3):285-294.

[59] Boswell R,Shelander D,Lee M,et al.Occurrence of gas hydrate in Oligocene Frio sand:Alaminos Canyon Block 818:Northern Gulf of Mexico[J].Marine and Petroleum Geology,2009,26(8):1499-1512.

[60] Uchida T,Tsuji T.Petrophysical properties of natural gas hydrates-bearing sands and their sedimentology in the Nankai Trough[J].Resource Geology,2004,54(1):79-87.

[61] Moridis G,Collett T,Pooladi-Darvish M,et al.Challenges,uncertainties and issues facing gas production from hydrate deposits in geologic systems[J].SPE Reservoir Evalation ＆ Engineering,2011,14(1):76-112.

[62] Holland M,Schultheiss P,Roberts J,et al.Observed gas hydrate morphologies in marine sediments,Proceedings of the 6th International Conference on Gas Hydrates,Vancouver,July 6—10,2008 [C].Vancouver:ICGH,2008.

[63] Gabitto J F,Tsouris C.Physical properties of gas hydrates:a review[J].Journal of Thermodynamics,2010,1-12.

[64] Klapproth A,Techmer K S,Klapp S A,et al.Microstructures of gas hydrates in porous media,11th International Conference on the Physics and Chemistry of ICE,Bremerhaven,July 23-28,2006[C].Bremerhaven:PCI,2006.

[65] Lee M W.Models for gas hydrate-bearing sediments inferred from hydraulic permeability and elastic velocities[R].USGS,2008.

[66] Fujii K,Yasuda M,Cho B,et al.Development of a monitoring system for the JOGMEC/NRCan/Aurora Mallik gas hydrate production test program,Proceedings of the 6th International Conference on Gas Hydrates,Vancouver,July 6—10,2008 [C].Vancouver:ICGH,2008.

[67] Riedel M,Bellefleur G,Dallimore S R,et al.Amplitude and frequency anomalies in regional 3D seismic data surrounding the Mallik 5L-38 research site,Mackenzie Delta,Northwest Territories,Canada[J].Geophysics,2006,71(6):B183-B191.

[68] Boswell R.Is gas hydrate energy within reach?[J].Science,2009,325(5943):957-958.

[69] Suzuki K,Ebinuma T,Narita H.Estimation of the in-situ permeabilities of Nankai Trough hydrate bearing aediments from Pressure Temparature Core Samplar (PTCS)Core Measurements,Offshore Technology Conference,Houston,May 5—8,2008[C].Houston:Offshore Technology Conference,2008.

[70] Cook A E,Goldberg D,Kleinberg R L.Fracture-controlled gas hydrate systems in the northern Gulf of Mexico[J].Marine and Petroleum Geology,2008,25(9):932-941.

[71] Dallimore S.Regional gas hydrate occurrence,permafrost conditions,and Cenozoic geology,Mackenzie Delta area[J].Geological Survey of Canada Bulletin,1999,544:31-43.

[72] Ginsburg G,Soloviev V,Matveeva T,et al.Sediment grain-size control on gas hydrate presence,Sites 994,995,and 997[R].Texas:Proceedings of the Ocean Drilling Program,2000:237-245.

[73] Yang S,Zhang H,Wu N.High concentration hydrate in disseminated forms obtained in Shenhu area,North Slope of South China Sea,Proceedings of the 6th International Conference on Gas Hydrates,Vancouver,July 6—10,2008 [C].Vancouver:ICGH,2008.

[74] Boswell R,Collett T S.Current perspectives on gas hydrate resources[J].Energy & Environmental Science,2011,4(4):1206-1215.

[75] Nimblett J,Ruppel C.Permeability evolution during the formation of gas hydrates in marine sediments[J].Journal of Geophysical Research,2003,108(B9):EPM2-1.

[76] Paull C K,Ussler W,Borowski W S,et al.Methane-rich plumes on the Carolina continental rise:associations with gas hydrates[J].Geology,1995,23(1):89-92.

[77] Trehu A M,Long P E,Torres M,et al.Three-dimensional distribution of gas hydrate beneath southern Hydrate Ridge:constraints from ODP Leg 204[J].Earth and Planetary Science Letters,2004,222(3):845-862.

[78] Collett T.Geology of marine gas hydrates and their global distribution,Offshore Technology Conference,Houston,May 5—8,2008[C].Houston:Offshore Technology Conference,2008.

[79] Guerin G,Goldberg D.Sonic waveform attenuation in gas hydrate-bearing sediments from the Mallik 2L-38 research well,Mackenzie Delta,Canada[J].Journal of Geophysical Research,2002,107(B5):EPM1-1-EPM1-11.

[80] Collett T,Ladd J.Detection of gas hydrate with downhole logs and assessment of gas hydrate concentrations (saturations)and gas volumes on the Blake Ridge with electrical resistivity log data[R].Texas:Proceedings of the Ocean Drilling Program,2000:179-191.

[81] Kim G Y,Yoo D G,Ryu B J,et al.Evidence of gas hydrate from UBGH2 Log Data in the Ulleung Basin,East Sea,Proceedings of the 7th International Conference on Gas Hydrates,Edinburgh,July 17—21,2011[C].Edinburgh:ICGH,2011.

[82] He J,Liu X.A comparison of methods that estimate gas hydrate saturation from well log velocity,Proceedings of the 7th International Conference on Gas Hydrates,Edinburgh,July 17—21,2011[C].Edinburgh:ICGH,2011.

[83] [JP+3]Ecker C,Dvorkin J,Nur A.Sediments with gas hydrates:internal structure from seismic AVO[J].Geophysics,1998,63(5):1659-1669.

[84] Kennedy W D,Herrick D C.Conductivity anisotropy in shale-free sandstone[J].Petrophysics,2004,45(1):38-58.

[85] Lee M W,Collett T S,Lewis K A.Anisotropic models to account for large borehole washout to estimate gas hydrate saturations in the Gulf of Mexico Joint Industry Project Leg II Alaminos Canyon 21 B well[J].Marine and Petroleum Geology,2012,34(1):85-95.

[86] Worthington P.Identifying the potential upside of hydrocarbon saturation from electric logs[J].SPE Reservoir Evaluation & Engineering,2009,12(1):53-67.

[87] Lee M W.Elastic velocities of partially gas-saturated unconsolidated sediments[J].Marine and Petroleum Geology,2004,21(6):641-650.

[88] Marion D,Nur A,Yin H,et al.Compressional velocity and porosity in sand-clay mixtures[J].Geophysics,1992,57(4):554-563.

[89] 邓少贵,李智强,范宜仁,等.斜井泥浆侵入仿真及其阵列侧向测井响应数值模拟[J].地球物理学报,2010,53(4):994-1000.

Deng Shaogui,Li Zhiqiang,Fan Yiren,et al.Numerical simulation of mud invasion and its array laterolog response in deviated wells[J].Chinese Journal of Geophysics,2010,53(4):994-1000.

[90] Ebeltoft H,Yousif M,Soergard E.Hydrate control during deepwater drilling:overview and new drilling-fluids formulations[J].SPE Drilling & Completion,2001,16(1):19-26.

[91] Ning F L,Jiang G S,Zhang L,et al.Analysis on Characteristics of Drilling Fluids Invading into Gas Hydrates-Bearing Formation,Proceedings of the 6th International Conference on Gas Hydrates,Vancouver,July 6—10,2008[C].Vancouver:ICGH,2008.

[92] 宁伏龙,张可霓,吴能友,等.钻井液侵入海洋含水合物地层的一维数值模拟研究[J].地球物理学报,2013,56(1):204-218.

Ning Fulong,Zhang Keni,Wu Nengyou,et al.The invasion of water-based drilling fluid into oceanic gas hydrate-bearing sediment:One-dimension numerical simulations[J].Chinese Journal of Geophysics,2013,56(1):204-218.

[93] Ning F L,Yu Y B,Jiang G S,et al.Numerical simulations of drilling mud invasion into the marine gas hydrate-bearing sediments[J].Advanced Materials Research,2012,366:378-387.

[94] Dai J,Banik N,Gillespie D,et al.Exploration for gas hydrates in the deepwater,northern Gulf of Mexico:Part II.Model validation by drilling[J].Marine and Petroleum Geology,2008,25(9):845-859.

天然气水合物储层测井评价及其影响因素

Well logging assessment of natural gas hydrate reservoirs and relevant influential factors

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