基于CT技术的低渗透油藏微观剩余油赋存状态OA
Microscopic occurrence state of remaining oil in low permeability reservoirs using CT technology
为实现对剩余油赋存状态从静态描述到动态定量分析,明确注水开发过程中剩余油在岩石孔隙中的动态赋存状态演化规律,构建一种多参数耦合的剩余油动态表征方法.基于计算机断层扫描(computed tomography,CT)技术开展微观驱替实验,通过综合分析剩余油总块数、平均体积、接触面积比、形状因子和欧拉数等参数影响,实现了驱替全过程中的剩余油赋存量、赋存位置和赋存形态的协同演化规律的定量表征.研究结果表明:驱替过程中剩余油总块数逐渐增加、平均体积逐渐减小、分布越来越分散,且岩心渗透率越大,变化程度越显著;随着驱替的进行,油相逐渐被剥离岩石壁面,接触面积比持续降低;在岩心亲水条件下,储层的强非均质性导致仍有部分残余油与岩石壁面接触,随着驱替的进行,连通性较好的簇状剩余油被动用的同时逐渐向其他类型剩余油转化,残余油状态时残余油赋存类型以簇状为主,形成以簇状残余油为主、其他类型并存的复杂赋存体系.基于上述结果,后期提高采收率的策略需由单一的驱替机制转向针对多种形态剩余油的复合动用机制,通过降低界面张力,进一步提高采收率.该研究为JD油田G76断块油藏高含水期的高效开发提供了微观机理支撑和宏观决策依据.
Accurate characterization of the microscopic occurrence states of remaining oil is essential for improving oil recovery in low-permeability reservoirs during the high water-cut stage.To advance the characterization of remaining oil from static description to dynamic quantitative analysis and to clarify the evolution of remaining oil within rock pore spaces during water flooding,a multi-parameter coupled dynamic characterization method is developed.Microscopic displacement experiments are conducted using computed tomography(CT)scanning technology.By comprehensively analyzing parameters including the total number of remaining oil clusters,average cluster volume,contact area ratio,shape factor,and Euler number,the coupled evolution of remaining oil quantity,spatial distribution,and morphological characteristics throughout the entire displacement process is quantitatively characterized.The results show that during water flooding,the total number of remaining oil clusters continuously increases while the average cluster volume decreases,resulting in an increasingly dispersed distribution;and the greater the core permeability,the more pronounced these trends become.As displacement proceeds,the oil phase is progressively detached from pore walls,leading to a continuous reduction in the oil-rock contact area ratio.Although the cores are water-wet,strong reservoir heterogeneity causes portions of residual oil remain in contact with the pore walls during the late development stage,suggesting the further recovery can be achieved by reducing interfacial tension in subsequent development stages.In addition,well-connected cluster-type remaining oil is mobilized and gradually transforms into other occurrence types during water flooding.At the residual oil stage,cluster-type remaining oil dominates,forming a complex occurrence system in which cluster residual oil coexists with other morphologies.This observation indicates that the enhanced oil recovery strategies should shift from a single displacement mechanism to a comprehensive mobilization mechanism targeting multiple residual oil morphologies.This study provides critical insights linking microscopic mechanisms to macroscopic development strategies and offer an important scientific basis for the efficient development of the G76 fault-block reservoir in the JD Oilfield during the high water-cut stage.
伊吉庆;冯其红;崔传智
中国石油大学(华东)石油工程学院,山东 青岛 266580||深层油气全国重点实验室(中国石油大学(华东)),山东 青岛 266580中国石油大学(华东)石油工程学院,山东 青岛 266580||深层油气全国重点实验室(中国石油大学(华东)),山东 青岛 266580中国石油大学(华东)石油工程学院,山东 青岛 266580||深层油气全国重点实验室(中国石油大学(华东)),山东 青岛 266580
能源科技
低渗透油藏高含水期水驱开发计算机断层扫描微观驱替实验微观剩余油
low-permeability reservoirshigh water cut stagewater floodingcomputed tomography(CT)microscopic displacement experimentmicroscopic remaining oil
《深圳大学学报(理工版)》 2026 (3)
281-289,9
National Natural Science Foundation of China(51974343) 国家自然科学基金资助项目(51974343)
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