基于深水浊积水道构型的流动单元分布规律

doi:10.11743/ogg20150216

石油与天然气地质 ›› 2015, Vol. 36 ›› Issue (2): 306-313.doi: 10.11743/ogg20150216

基于深水浊积水道构型的流动单元分布规律

万琼华^1,2, 吴胜和¹, 陈亮³, 林煜¹, 梁杰², 张佳佳¹, 路瑶¹

1. 中国石油大学(北京) 地球科学学院, 北京 102249;
2. 中海石油(中国)有限公司深圳分公司, 广东广州 510240;
3. 中海石油研究总院, 北京 100028

收稿日期:2014-10-15 修回日期:2015-02-27 出版日期:2015-04-08 发布日期:2015-05-13
通讯作者: 吴胜和(1963-),男,教授、博士生导师,储层地质学、油藏描述及三维地质建模.E-mail:reser@cup.edu.cn. E-mail:reser@cup.edu.cn
作者简介:万琼华(1986-),女,工程师,精细油藏描述及开发地质研究.E-mail:wanqh@cnooc.com.cn.
基金资助:
国家科技重大专项(2011ZX05030-005),(2011ZX05009-003);国家自然科学基金青年科学基金项目(40902035).

Analysis of flow unit distribution based on architecture of deep-water turbidite channel systems

Wan Qionghua^1,2, Wu Shenghe¹, Chen Liang³, Lin Yu¹, Liang Jie², Zhang Jiajia¹, Lu Yao¹

1. College of Geoscience, China University of Petroleum, Beijing 102249, China;
2. Shenzhen Branch of CNOOC Ltd., Guangzhou, Guangdong 510240, China;
3. CNOOC Research Institute, Beijing 100028, China

Received:2014-10-15 Revised:2015-02-27 Online:2015-04-08 Published:2015-05-13

摘要/Abstract

摘要：

深水浊积水道发育位置与形成过程复杂，目前国内外学者致力于其沉积机理和模式的研究。相对于陆上沉积，这些研究成果尚不能高效地运用到油气田开发中。因此，将构型模式与流动单元研究相结合的意义重大，表现为：①已有的构型级次的划分能够有效地指导流动单元渗流屏障和连通体的层次分析；②已有的沉积模式研究能够约束流动单元的分布规律；③二者的结合能将构型模式研究成果运用到油气田开发中。为此，以西非尼日尔三角洲深水浊积水道储层为例，在储层构型级次划分的基础上，分级次识别了渗流屏障和连通体；并运用多参数流动单元的划分方法，将储层划分为A，B，C，D 4类流动单元；最后，在构型模式的指导下进行了流动单元的单井解释及单一水道剖面与复合水道平面的流动单元分布特征研究，并以此指导油气田开发。研究表明：在单一水道级次，不同类型的单一水道内部流动单元发育类型和分布特征存在差异，流动单元的分布规律受控于不同单一水道类型的分布规律；在复合水道级次，水道体系不同时期水道迁移与叠置样式的差异，造就了流动单元平面分布特征的差异性。

关键词: 流动单元, 渗流屏障, 连通体, 浊积水道, 尼日尔三角洲

Abstract:

The study of deep-water turbidite channels(with their wired locations and complicated forming process)has been mostly about their sedimentary mechanism and models.However,the study results could not be effectively applied in actual development of oil and gas fields.We suggest that a combination of architecture model with flow units of the channels be a better solution to the problem for the following reasons:①available architecture division of the channels can be used to guide directly and effectively a hierarchy analysis of seepage barriers and interconnected bodies of flow units in the channels;②existing sedimentary models can be resorted to constraint the distribution laws of the flow units;and③a combination of①and②can be used to guide oil and gas development.We took a deep-water submarine fan reservoir of Niger delta in West Africa as an example to illustrate the idea.Based on available reservoir architecture division,we identified seepage barriers and interconnected bodies and divided the reservoir into 4 types(A,B,C and D)of flow units through multi-parameters-based flow unit identification.We then tried to interprete flow units of single well and study profile distribution characteristics of single channel and plain distribution characteristics of composite channels with the architecture model as a guidance.The results were finally applied to the development of oil and gas fields.The resarch shows that the types and distribution features of flow units of different single channels may vary greatly from one to ano-ther and the distribution of these flow units were controlled by the distribution pattern of different types of single channels.For composite channels,the migration and stacking patterns of the channels systems at different stages led to a difference in flow unit distribution characteristics.

Key words: flow unit, seepage barrier, interconnected sand body, turbidite channel, Niger Delta Basin

中图分类号:

TE121.3

万琼华,吴胜和,陈亮,等. 基于深水浊积水道构型的流动单元分布规律[J]. 石油与天然气地质, 2015, 36(2): 306-313. doi: 10.11743/ogg20150216 Wan Qionghua,Wu Shenghe,Chen Liang,et al. Analysis of flow unit distribution based on architecture of deep-water turbidite channel systems[J]. Oil & Gas Geology, 2015, 36(2): 306-313. doi: 10.11743/ogg20150216

参考文献

[1] 吕福亮,贺训云,武金云,等.世界深水油气勘探现状、发展趋势及对我国深水勘探的启示[J].中国石油勘探,2007,(6):28-31. Lü Fuliang,He Xunyun,Wu Jinyun,et al.Current situation and ten-dency of deepwater oil and gas exploration in the world[J].China Petroleum Exploration,2007,(6):28-31.
[2] 李大伟,李德生,陈长民,等.深海扇油气勘探综述[J].中国海上油气,2007,19(1):18-24. Li Dawei,Li Desheng,Chen Changmin,et al.An overview of hydrocarbon exploration in deep submarine fans[J].China Offshore Oil and Gas,2007,19(1):18-24.
[3] 江怀友,赵文智,闫存章,等.世界海洋油气资源与勘探模式概述[J].海相油气地质,2008,13(3):5-10. Jiang Huaiyou,Zhao Wenzhi,Yan Cunzhang,et al.Review on marine petroleum resources and exploration models in the globe[J].Marine Origin Petroleum Geology,2008,13(3):5-10.
[4] 张抗,董立,温友建.俄罗斯-前苏联石油产区的战略接替及其启示[J].石油与天然气地质,2012,33(1):148-158. Zhang Kang,Dong Li,Wen Youjian.Strategic replacement of oil producing area in Russia-former Soviet Union and its enlightenment[J].Oil & Gas Geology,2012,33(1):148-158.
[5] 牛成民.渤海南部海域莱州湾凹陷构造演化与油气成藏[J].石油与天然气地质,2012,33(3):424-431. Niu Chengmin.Tectonic evolution and hydrocarbon accumulation of Laizhouwan depression in southern Bohai Sea[J].Oil & Gas Geology,2012,33(3):424-431.
[6] Wynn R B,Cronin B T,Peakall J.Sinuous deep-water channels:Genesis,geometry and architecture[J].Marine and Petroleum Geology,2007,24:341-387.
[7] Beaubouef R T,Abreu V,Van Wagoner J C.Basin 4 of the Brazos Trinity slope system,western Gulf of Mexico[C]//Roberts H H,Ro-sen N C,Filton R H,et al.Shelf margin deltas and linked down slope petroleum system:Globle significance and future exploration potential.Gulf Coast Section SEPM Foundation,the 23rd Annual Bob F.Perkins Research Conference,2003:45-66.
[8] Mutti E,Normark W.Comparing examples of modern and ancient turbidite systems:Problems and concepts[M].London:Graham and Trotman,1987:1-38.
[9] Richard L.Integrated three-dimensional modeling approach of stacked turbidity channels[J].AAPG Bulletin,2007(11):1603-1618.
[10] 刘忠宝,杨圣彬,焦存礼,等.塔里木盆地巴楚隆起中、下寒武统高精度层序地层与沉积特征[J].石油与天然气地质,2012,33(1):70-76. Liu Zhongbao,Yang Shengbin,Jiao Cunli,et al.High resolution sequence stratigraphy and sedimentary characteristics of the Middle-Lower Cambrian in Bachu Uplift,the Tarim Basin[J].Oil & Gas Geology,2012,33(1):70-76.
[11] Hearn C L,Ebanks W J,Tye R S,et al.Geoiogical factors influencing reservoir performance of Hartog Draw Field,Wyoming[J].Journal of Canadian Petroleum Technology,1984,36(9):1335-1344.
[12] Ebanks W J Jr.Flow unit concept-integrated approach to reservoir description for engineering projects[J].AAPG Bulletin,1987,71(5):551-552.
[13] 计秉玉.国内外油田提高采收率技术进展与展望[J].石油与天然气地质,2012,33(1):111-117. Ji Bingyu.Progress and prospects of enhanced oil recovery technologies at home and abroad[J].Oil & Gas Geology,2012,33(1):111-117.
[14] 林煜,吴胜和,万琼华,等.深水浊积水道体系构型模式研究[J].地质论评,2013,59(3):510-520. Lin Yu,Wu Shenghe,Wan Qianghua,et al.Research on architecture model of deepwater turbidity channel system:A case study of a deepwater research area in Niger Delta Basin,West Africa[J].Geological Review,2013,59(3):510-520.
[15] 邓荣敬,邓运华,于水,等.尼日尔三角洲盆地油气地质与成藏特征[J].石油勘探与开发,2008,35(6):755-762. Deng Rongjin,Deng Yunhua.Yu Shui,et al.The oil and gas geology and accumulation characteristics of Niger delta basin[J].Petroleum Exploration and Development,2008,35(6):755-762.
[16] 吴胜和,王仲林.陆相储层流动单元研究的新思路[J].沉积学报,1999,17(2):252-257. Wu Shenghe,Wang Zhonglin.The new way of thinking in terrestrial facies of reservoir flow units[J].Acta Sedimentologica Sinica,1999,17(2):252-257.
[17] 吴胜和.储层表征与建模[M].北京:石油工业出版社,2010:228-234. Wu Shenghe.Reservoir characterization & modeling[M].Beijing:Petroleum Industry Press,2010:228-234.
[18] 万琼华,吴胜和,林煜,等.深水浊积水道储层多参数流动单元划分方法及其分布规律研究[J].高校地质学报,2014,20(2):315-323. Wan Qionghua,Wu Shenghe,Lin Yu,et al.Multi-parameter technology on the study of flow units division and their distribution in deep-water turbidity channel reservoir[J].Geological Journal of China Universities,2014,20(2):315-323.

基于深水浊积水道构型的流动单元分布规律

Analysis of flow unit distribution based on architecture of deep-water turbidite channel systems

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