水驱开发多层油藏井间连通性反演模型

赵辉; 康志江; 孙海涛; 张贤松; 李颖

doi:10.11698/PED.2016.01.12

石油勘探与开发 >

2016 , Vol. 43 >Issue 1: 99 - 106

DOI: https://doi.org/10.11698/PED.2016.01.12

油气田开发

水驱开发多层油藏井间连通性反演模型

赵辉 ,
康志江 ,
孙海涛 ,
张贤松 ,
李颖

展开

1. 长江大学石油工程学院；
2. 中国石油化工股份有限公司石油勘探开发研究院；
3. 海洋石油高效开发国家重点实验室

赵辉（1984-）,男,山东乐陵人,博士,长江大学石油工程学院副教授,主要从事油气田开发、油藏工程及优化控制工程方面的研究。地址：湖北省武汉市蔡甸区大学路一号,长江大学石油工程学院,邮政编码：430100。E-mail: zhaohui-712@163.com

网络出版日期: 2017-01-01

基金资助

国家科技重大专项（2011ZX05014）; 国家自然科学基金资助项目（51344003）

收起

An interwell connectivity inversion model for waterflooded multilayer reservoirs

ZHAO Hui ,
KANG Zhijiang ,
SUN Haitao ,
ZHANG Xiansong ,
LI Ying

Expand

1. College of Petroleum Engineering, Yangtze University, Jingzhou 434023, China;
2. Sinopec Exploration & Production ResearchInstitute, Beijing 100728, China;
3. State Key Laboratory of Offshore Oil Exploitation, Beijing 100727, China

Online published: 2017-01-01

Fold

摘要

针对当前井间连通性模型只能预测产液动态变化、无法计算油水两相动态且不能分层进行连通性分析等局限性,建立了新的可模拟油水动态的多层油藏井间连通性模型。模型将油藏系统分层离散成一系列由井间传导率和连通体积等参数表征的井间连通单元,并以连通单元为模拟对象进行物质平衡方程计算,通过考虑定液、定压两种生产模式实现压力求解和井间流量计算,结合前缘推进理论建立了井间饱和度追踪计算方法,最终得出井点处各层的油水产出动态;以此为基础利用随机扰动近似法和投影梯度法等通过动态拟合建立了模型参数反演方法。实例应用显示,所建模型取得了较好的动态拟合和预测效果,反演后的连通模型参数与实际油藏地质特征相吻合,验证了方法的正确性;相比当前连通性方法,模型能实时获得分层井间流量分配系数、单井产液和产油劈分系数等信息,可以更准确地反映油藏平面及纵向的油水流动关系和生产措施变化,指导油田实际生产。图8参28

关键词： 多层油藏; 井间连通性; 反演模型; 井间连通单元; 井间流量分配系数; 油井产量劈分系数

本文引用格式

赵辉 , 康志江 , 孙海涛 , 张贤松 , 李颖 . 水驱开发多层油藏井间连通性反演模型[J]. 石油勘探与开发, 2016 , 43(1) : 99 -106 . DOI: 10.11698/PED.2016.01.12

Abstract

In view of the limitations that the current connectivity model can only forecast the fluid production dynamic change, can’t calculate the dynamics of oil and water phases, and can’t analyze the connectivity between wells layer by layer, this study establishes a new interwell connectivity model for multilayer reservoirs which can simulate dynamics of oil and water between wells. The model hierarchically separates the reservoir system into a series of interwell connecting units characterized by parameters such as conductivity and control volume, and by using the material balance equation, the pressure and interwell flow at constant liquid production and constant pressure is calculated with the connecting unit as simulation object, which are combined with the frontal advance theory to establish interwell saturation tracking calculation method, and finally water production dynamics of every layer at well points can be worked out. On this basis, using simultaneous perturbation stochastic approximation method and gradient projection method, a model parameter inversion method is set up by dynamic fitting. The application cases show that the model has good dynamic fitting and prediction effect, inversed model parameters and the actual geological parameters coincide with well, verifing the validity of the method. Compared with the current connectivity method, it can obtain the real-time model of hierarchical interwell flow rate distribution coefficient, liquid production of single well and oil split coefficient and other information, and reflect the reservoir horizontal and vertical oil-water flow relation more accurately, providing guidance for production measure adjustment in oilfield.

Key words： multilayer reservoir; interwell conectivity; inversion model; interwell connecting unit; interwell flow rate distribution coefficient; oil split coefficient

参考文献

[1] 康志宏, 陈琳, 鲁新便, 等. 塔河岩溶型碳酸盐岩缝洞系统流体动态连通性研究[J]. 地学前缘, 2012, 19(2): 110-120.
KANG Zhihong, CHEN Lin, LU Xinbian, et al. Fluid dynamic connectivity of karst carbonate reservoir with fracture & cave system in Tahe oilfield[J]. Earth Science Frontiers, 2012, 19(2): 110-120.
[2] 赵伦, 王进财, 陈礼, 等. 砂体叠置结构及构型特征对水驱规律的影响: 以哈萨克斯坦南图尔盖盆地Kumkol油田为例[J]. 石油勘探与开发, 2014, 41(1): 86-94.
ZHAO Lun, WANG Jincai, CHEN Li, et al. Influences of sandstone superimposed structure and architecture on waterflooding mechanisms: A case study of Kumkol Oilfield in the South Turgay Basin, Kazakhstan[J]. Petroleum Exploration and Development, 2014, 41(1): 86-94.
[3] 封从军, 鲍志东, 杨玲, 等. 三角洲前缘水下分流河道储集层构型及剩余油分布[J]. 石油勘探与开发, 2014, 41(3): 323-329.
FENG Congjun, BAO Zhidong, YANG Ling, et al. Reservoir architecture and remaining oil distribution of deltaic front underwater distributary channel[J]. Petroleum Exploration and Development, 2014, 41(3): 323-329.
[4] 杜鹃, 杨树敏. 井间微地震检测技术现场应用效果分析[J]. 大庆石油地质与开发[J]. 2007, 26(4): 120-122.
DU Juan, YANG Shumin. Analysis to the field application effect of inner well microseismic monitoring technique[J]. Petroleum Geology & Oilfield Development in Daqing, 2007, 26(4): 120-122.
[5] 易斌, 崔文彬, 鲁新便, 等. 塔河油田碳酸盐岩缝洞型储集体动态连通性分析[J]. 新疆石油地质, 2011, 32(5): 469-472.
YI Bin, CUI Wenbin, LU Xinbian, et al. Analysis of dynamic connectivity on carbonate reservoir with fracture and cave in Tahe field, Tarim basin[J] Xinjiang Petroleum Geology, 2011, 32(5): 469-472.
[6] HEFFER K J, FOX R J, MCGILL C A, et al. Novel techniques show links between reservoir flow directionality, earth stress, fault structure and geomechanical changes in mature waterfloods[R]. SPE 30711, 1995.
[7] ALBERTONI A, LAKE L W. Inferring interwell connectivity only from well-rate Fluctuations in water floods[R]. SPE 83381, 2003.
[8] YOUSEF A A, GENTIL P, JENSEN J L, et al. A capacitance model to infer interwell connectivity from production and injection rate fluctuations[R]. SPE 95322, 2005.
[9] YOUSEF A A, JENSEN J L, LAKE L W. Integrated interpretation of interwell connectivity using injection and production fluctuations[J]. Mathematical Geosciences, 2009: 81-102.
[10] WEBER D, EDGAR T F, LAKE L W, et al. Improvements in capacitance-resistive modeling and optimization of large scale reservoirs[R]. SPE 121299, 2009.
[11] SAYARPOUR M, KABIR, C S, LAKE L W. Field applications of capacitance-resistance models in waterfloods[R]. SPE 114983, 2009.
[12] NGUYEN A P, KIM J S, LAKE L W, et al. Integrated capacitance resistive model for reservoir characterization in primary and secondary recovery[R]. SPE 147344, 2011.
[13] SALAZAR M, GONZALEZ H, MATRINGE S, et al. Combining decline-curve analysis and capacitance-resistance models to understand and predict the behavior of a mature naturally fractured carbonate reservoir under gas injection[R]. SPE 153252, 2012.
[14] CAO F, LUO H S, LAKE L W. Development of a fully coupled two-phase flow based capacitance resistance model(CRM)[R]. SPE 169485, 2014.
[15] MORENO G A, LAKE L W. On the uncertainty of interwell connectivity estimations from the capacitance-resistance model[J]. Petroleum Science, 2014, 11(2): 265-271.
[16] 赵辉, 李阳, 高达, 等. 基于系统分析方法的油藏井间动态连通性研究[J]. 石油学报, 2010, 31(4): 633-636.
ZHAO Hui, LI Yang, GAO Da, et al. Research on reservoir interwell dynamic connectivity using systematic analysis method[J]. Acta Petrolei Sinica, 2010, 31(4): 633-636.
[17] GHERABATI S A, HUGHES R G, ZHANG H, et al. A large scale network model to obtain interwell formation characteristics[R]. SPE 153386, 2012.
[18] 张建国, 杜殿发, 侯建, 等. 油气层渗流力学[M]. 东营: 中国石油大学出版社, 2009.
ZHANG Jiangguo, DU Dianfa, HOU Jian, et al. Oil and gas seepage mechanics[M]. Dongying: China University of Petroleum Press, 2009.
[19] 李淑霞, 谷建伟. 油藏数值模拟基础[M]. 东营: 中国石油大学出版社, 2009.
LI Shuxia, GU Jianwei. The basis for reservoir numerical simulation[M]. Dongying: China University of Petroleum Press, 2009.
[20] 宋考平, 吴玉树, 计秉玉. 水驱油藏剩余油饱和度分布预测的 φ 函数法[J]. 石油学报, 2006, 27(3): 91-95.
SONG Kaopin, WU Yushu, JI Bingyu. A φ -function method for estimating distribution of residual oil saturation in water drive reservoir[J]. Acta Petrolei Sinica, 2006, 27(3): 91-95.
[21] 李成勇, 柳金城, 李晓茹, 等. 多层合采油藏油水井产量劈分原理及应用[J]. 大庆石油地质与开发, 2010, 29(1): 55-59.
LI Chengyong, LIU Jincheng, LI Xiaoru, et al. Principles and application of production allocation for oil and water wells in multilayer commingled development oil reservoir[J]. Petroleum Geology & Oilfield Development in Daqing, 2010, 29(1): 55-59.
[22] 李凤琴, 刘丽琼, 丁全胜, 等. 分层累计吸水量劈分方法研究[J]. 河南石油, 2005, 19(5): 28-29.
LI Fengqin, LIU Liqiong, DING Quansheng, et al. A study on calculation of accumulative water-intake rate of separate layer[J]. Henan Petroleum, 2005, 19(5): 28-29.
[23] 曹光胜. 厚层块状稠油油藏产量劈分方法研究[J]. 特种油气藏, 2006, 13(1): 58-60.
CAO Guangsheng. Study on production split in thick massive heavy oil reservoir[J]. Special Oil & Gas Reservoirs, 2006, 13(1): 58-60.
[24] WANG C H, LI G M, REYNOLDS A C. Production optimization in closed-loop reservoir management[R]. SPE 109805, 2007.
[25] SPALL J C. Adaptive stochastic approximation by the simultaneous perturbation method[J]. IEEE Transactions on Automatic Control, 2000, 45(10): 1839-1853.
[26] ZHAO Hui, LI Yang, YAO Jun, et al. Theoretical research on reservoir closed-loop production management[J]. Science China: Technological Sciences, 2011, 54(10): 2815-2824.
[27] 赵辉, 李阳, 康志江. 油藏开发生产鲁棒优化方法[J]. 石油学报, 2013, 34(5): 947-953.
ZHAO Hui, LI Yang, KANG Zhijiang. Robust optimization in oil reservoir production[J]. Acta Petrolei Sinica, 2013, 34(5): 947-953.
[28] ZHAO H, CHEN C H, DO S, et al. Maximization of a dynamic quadratic interpolation model for the production optimization[J]. SPE Journal, 2013, 18(6): 1012-1025.

Options

文章导航

模态框（Modal）标题

摘要

本文引用格式

Abstract

参考文献