流动单元划分新方案及其在临南油田的应用

胡文瑄; 朱东亚; 陈庆春; 王秀鹏; 曹学伟

流动单元划分新方案及其在临南油田的应用

1.
南京大学地球科学系, 江苏南京 210093
2.
胜利油田临盘采油厂地质研究所, 山东临邑 251500

基金项目:

国家科技部基础研究开发规划项目 2004CB720503

详细信息

作者简介:
胡文瑄(1959—), 男, 教授, 矿床学专业, 现主要从事油气成藏与流体地球化学研究.E-mail：huwx@nju.edu.cn

中图分类号: P618.13
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出版历程
- 收稿日期: 2005-06-29
- 刊出日期: 2006-03-25

A New Method for Flow Unit Division and Its Application in Linnan Oilfield

1.
Department of Earth Sciences, Nanjing University, Nanjing 210093, China
2.
Geology Research Institute of Linpan Oilfield, Linyi 251500, China

摘要

摘要: 把沉积学与储层物性相结合, 从流动单元体系的角度出发, 提出了流动单元划分的新方案.在流动单元体系内部划分出流动单元、亚流动单元和渗流区3个不同层次.在储层精细小层对比的基础上, 首先根据区域内连续分布的隔层把储层分成几个独立的流体压力系统, 即流动单元; 然后再根据不连续分布的隔层, 把一个流动单元进一步分成若干个亚流动单元; 最后根据储层物性的差别把流动单元/亚流动单元划分成不同的渗流区.按照这个思路, 选取临南油田的典型高产区块———以三角洲前缘亚相沉积为主的夏52块砂三中段三砂组, 进行了流动单元、亚流动单元和渗流区的划分, 共划分出7个流动单元、7个亚流动单元和63个渗流区, 这样划分出来的流动单元体系同时包括了油藏整体与局部细节的特征, 为油藏开发提供了详细的地质依据, 也在实际应用中取得了良好的效果.
- 流动单元 /
- 划分方案 /
- 渗流区 /
- 储层物性 /
- 临南油田
Abstract: A new method for flow unit division is proposed which combines sedimentology and the physical properties of a reservoir. The flow unit system is sub-divided into three hierarchies: flow unit, sub-flow unit and seepage zone. On the basis of elaborate sandbody correlation and according to the continuously distributed insulating layers, the reservoir is divided into several individual fluid-pressure systems, namely, flow units. A flow unit is divided into several sub-flow units according to the discontinuously distributed insulating layers. Finally, a sub-flow unit or flow unit is divided into several seepage zones according to the physical properties of the reservoir. A typical prolific block in Linnan oilfield, Xia 52, was selected for this study. According to the dividing method, Xia 52 was divided into 7 flow units, 7 sub-flow units and 63 seepage zones. Such fluid unit system, which includes both frame and local detail characteristics of the reservoir, provides detail geological information for reservoir development. Good effect has been achieved by applying such method in Linnan oilfield.
- flow unit /
- division method /
- seepage zone /
- reservoir physical property /
- Linnan oilfield

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图 1 夏52块沙三中段三砂组韵律层的划分与对比

1¹代表 1小层1砂体, 其他相同

下载: 全尺寸图片幻灯片

图 2 2小层1砂体和2砂体亚流动单元沉积微相分布图及两者之间隔层等厚线和连通区域分布

a. 2小层1砂体亚流动单元沉积微相分布; b. 2小层1砂体亚流动单元和2砂体亚流动单元之间的隔层等厚线和连通区域分布; c. 2小层2砂体亚流动单元沉积微相分布

Fig. 2. Microfacies of 2¹ and 2² sub-fluid units, and isopaches of the insulating layer and the distribution of connective area between them

下载: 全尺寸图片幻灯片

图 3 沙三中段三砂组沉积微相和渗流区分布

a. 1小层2砂体, 属三角洲平原-三角洲前缘亚相沉积, 沉积微相类型以分支河道沉积为主, 渗流区类型主要是A、B和C型; b. 4小层1砂体, 属三角洲前缘亚相沉积, 沉积微相类型主要是砂坝, 渗流区类型有A、B、C和D型

Fig. 3. Distribution of seepage zones and microfacies of the 3rd member of Shahejie Formation

下载: 全尺寸图片幻灯片

图 4 3小层2个不同亚流动单元油水动态变化比较

Fig. 4. Comparison of the oil-water dynamic changes between 3¹ and 3² sub-flow units

下载: 全尺寸图片幻灯片

表 1 流动单元体系划分

Table 1. Classification of flow unit system

表 2 各小层单砂体之间连通井段统计

Table 2. Statistics on the connective wells between individual sandbodies of each substratum

表 3 沙三中段三砂组流动单元体系划分

Table 3. Division of the flow unit system of the 3rd member, the 3rd member of Shahejie Formation

表 4 各类型渗流区孔隙度、渗透率及测井曲线特征

Table 4. Porosity, permeability and well log characteristics of each seepage zone

参考文献(26)

[1]	Amaefule, J. O., Altunbay, M., Kersey, D. G., 1996. Enhanced reservoir description: Using core and log data to identify hydraulic(flow)units and predict permeability in uncored intervals/well. SPE26435, presented at the 68th annual conference and exhibition.
[2]	Ebanks, W.J., 1987. Flow unit concept-Integrated approach to reservoir description for engineering project. AAPG Bulletin, 71(5): 551-552.
[3]	Cai, Z., Zeng, F.F., 2000. Micro-facies models and distributions of residual oil in Linnan oilfield. Journal of University of Petroleum(Science Edition), 24(1): 44-47 (in Chinese with English abstract).
[4]	Dou, Z. L., 2000. Fluid unit model of fluvial reservoir of Guantao Member in Gudong Oil-field and distribution of residual oil. Petroleum Exploration and Development, 27(6): 50-52(in Chinese with English abstract).
[5]	Hamlin, H.S., Dutton, S.P., Seggie, D., et al., 1996. Depositional controls reservoir properties in a braid-delta sandstone, Tarrawazza oilfield, South Australia. AAPG Bulletin, 80(2): 139-156.
[6]	Hearn, C.L., Ebanks, W.J., Tye, R.S., et al., 1984. Geological factors influencing reservoir performance of the Hartzog Draw field, Wyoming. Journal of Petroleum Technology, 36: 1335-1344.
[7]	Jiao, Y.Q., Li, S.T., Li, Z., et al., 1995. Sediment system of sinuous river and lacustrine delta and inner structure analysis of typical sandbodies. Geologyical Publishing House, Beijing, 1-2(in Chinese).
[8]	Peng, S.M., Yin, Z.J., Chang, X.J., et al., 2001. A new method for quantitive research of terrestrial reservoir flow unit. Petroleum Exploration and Development, 28 (5): 68-70(in Chinese with English abstract).
[9]	Qiu, Y.N., Chen, Z.Q., 1996. Reservoir characteristics. Petroleum Industry Press, Beijing.
[10]	Robert, G. L., Entzminger, D., Sakurai, S., 2001. Highresolution sequence stratigraphic approach to carbonate reservoir characterization for understanding flow units and petrophysical properties: Example from Permian North Cowden Field, West Texas. AAPG Annual Convention Abstract.
[11]	Song, Z.Q., Gao, X.J., Tan, C.Q., et al., 2002. Study on fluid unit of conglomerate reservoir of the 8th zone in Kelamayi oilfield. Xinjiang Petroleum Geology, 23(2): 150-153(in Chinese with English abstract).
[12]	Tan, C.W., Song, Z.Q., Wu, S.B., et al., 2002. Flow units of the block Bo-21 sandstone reservoir in the Gudao oilfield, Jiyang depression. Geological Review, 48(3): 330-334(in Chinese with English abstract).
[13]	Wagoner, J.C., Mitchum, R.M., Campion, K.M., et al., 1999. Siliciclastic sequence stratigraphy in well logs, cores and outcrops: Concepts for high-resolution correlations of time and facies. AAPG Methods in Exploration Series, 7: 55.
[14]	Wu, S.H., Wang, Z.L., 1999. A new methold of non-marine reservoir flow unit study. Acta Sedimentologica Sinica, 17(7): 252-257(in Chinese with English abstract).
[15]	Zeng, D.Q., Li, Z.C., Song, G.Y., et al., 2002. Base level cycle and reservoir flow unit of Shasan upper part in Pucheng oilfield. Acta Petrolei Sinica, 23(3): 39-42 (in Chinese with English abstract).
[16]	Zhu, D.Y., Hu, W.X., Cao, X.W., et al., 2004. Classification and distribution of insulating layers in Linnan oilfield. Earth Science-Journal of China University of Geosciences, 29(2): 211-218(in Chinese with English abstract).
[17]	蔡忠, 曾发富, 2002. 临南油田沉积微相模式及剩余油分布. 石油大学学报(自然科学版), 24(1): 44-47.
[18]	窦之林, 2000. 孤东油田馆陶组河流相储集层流动单元模型与剩余油分布规律研究. 石油勘探与开发, 27(6): 50 52.
[19]	焦养泉, 李思田, 李祯, 等, 1995. 曲流河与湖泊三角洲沉积体系及典型骨架砂体内部构成分析. 北京: 中国地质大学出版社, 1-2.
[20]	彭仕宓, 尹志军, 常学军, 等, 2001. 陆相储集层流动单元定量研究新方法. 石油勘探与开发, 28(5): 68-70.
[21]	裘怿楠, 陈子琪, 1996. 油藏描述. 北京: 石油工业出版社.
[22]	宋子齐, 高兴军, 谭成仟, 等, 2002. 克拉玛依油田八区克上组砾岩油藏流动单元研究. 新疆石油地质, 23(2): 150 153.
[23]	谭成仵, 宋子齐, 吴少波, 等, 2002. 济阳坳陷孤岛油田渤21断块砂岩油藏流动单元研究. 地质论评, 48(3): 330-334.
[24]	吴胜和, 王仲林, 1999. 陆相储层流动单元研究的新思路. 沉积学报, 17(2): 252-257.
[25]	曾大乾, 李中超, 宋国英, 等, 2002. 濮城油田沙三上地层基准面旋回及储层流动单元. 石油学报, 23(3): 39-42.
[26]	朱东亚, 胡文, 曹学伟, 等, 2004. 临南油田隔层类型划分及其分布规律研究. 地球科学——中国地质大学学报, 29(2): 211-218.