Remaining oil distribution characteristics in an oil reservoir with ultra-high water-cut

An accurate mapping and understanding of remaining oil distribution is very important for water control and stabilize oil production of mature oilfields in ultra-high water-cut stage.Currently,the Tuo-21 Fault Block of the Shengtuo Oilfield has entered the stage of ultra-high water cut(97.2%).Poor adaptability of the well pattern,ineffective water injection cycle and low efficiency of engineering measures(such as workover,re-perforation and utilization of high-capacity pumps)are the significant problems in the ultra-high water-cut reservoir.In order to accurately describe the oil and water flow characteristics,relative permeability curves at high water injection multiple(injected pore volume)and a semiquantitative method is applied to perform fine reservoir simulation of the Sand group 3e7 in the Block.An accurate reservoir model is built and history matching is performed.The distribution characteristics of remaining oil in lateral and vertical directions are quantitatively simulated and analyzed.The results show that the numerical simulation considering relative permeability at high injection multiple can reflect truly the remaining oil distribution characteristics after water flooding in an ultrahigh water-cut stage.The distribution of remaining oil saturation can be mapped more accurately and quantitatively by using the‘four-points and five-types’classification method,providing a basis for potential tapping of various remaining oil types of oil reservoirs in late-stage of development with high water-cut.

Water-cut rising mechanism and optimized water injection technology for deepwater turbidite sandstone oilfield: A case study of AKPO Oilfield in Niger Delta Basin, West Africa

Through the analysis of the reservoir connection relationship and the water-cut rising rules after water breakthrough in the highly volatile oil AKPO oilfield, a new model of water-cut rising was established, and the timing and strategy of water injection were put forward. The water-cut rising shapes of producers after water breakthrough can be divided into three types, and their water-cut rising mechanism is mainly controlled by reservoir connectivity. For the producers which directly connect with injectors in the single-phase sand body of the single-phase channel or lobe with good reservoir connectivity, the water-cut rising curve is "sub-convex". For the producers which connect with injectors through sand bodies developed in multi-phases with good inner sand connectivity but poorer physical property and connectivity at the overlapping parts of sands, the response to water injection is slow and the water-cut rising curve is "sub-concave". For the producers which connect with injectors through multi-phase sand bodies with reservoir physical properties, connectivity in between the former two and characteristics of both direct connection and overlapping connection, the response to water injection is slightly slower and the water-cut rising curve is "sub-S". Based on ratio relationship of oil and water relative permeability, a new model of water cut rising was established. Through the fitting analysis of actual production data, the optimal timing and corresponding technology for water injection after water breakthrough were put forward. Composite channel and lobe reservoirs can adopt water injection strategies concentrating on improving the vertical sweep efficiency and areal sweep efficiency respectively. This technology has worked well in the AKPO oilfield and can guide the development of similar oilfields.

Experimental study on surface-active polymer flooding for enhanced oil recovery: A case study of Daqing placanticline oilfield, NE China

Experiments on surface-active polymer flooding for enhanced oil recovery were carried out by detection analysis and modern physical simulation technique based on reservoirs and fluids in Daqing placanticline oilfield.The experimental results show that the surface-active polymer is different from other common polymers and polymer-surfactant systems in molecular aggregation,viscosity and flow capacity,and it has larger molecular coil size,higher viscosity and viscosifying capacity,and poorer mobility.The surface-active polymer solution has good performance of viscosity-increasing and viscosity retention,and has good performance of viscoelasticity and deformability to exert positive effects of viscosifying and viscoelastic properties.Surface-active polymer can change the chemical property of interface and reduce interfacial tension,making the reservoir rock turn water-wet,also it can emulsify the oil into relatively stable oil-in-water emulsion,and emulsification capacity is an important property to enhance oil washing efficiency under non-ultralow interfacial tension.The surface-active polymer flooding enlarges swept volume in two ways:Microscopically,the surface-active polymer has mobility control effect and can enter oil-bearing pores not swept by water to drive residual oil,and its mobility control effect has more contribution than oil washing capacity in enhancing oil recovery.Macroscopically,it has plugging capacity,and can emulsify and plug the dominant channels in layers with high permeability,forcing the injected fluid to enter the layer with medium or low permeability and low flow resistance,and thus enlarging swept volume.

物理模拟融合油藏精细刻画法表征特低渗油藏中高含水期剩余油分布

中国低渗透油藏分布广泛,其中大部分区块已进入中高含水期,并且由于剩余油类型及成因不明确导致采出程度普遍较低,因此延长低渗透油藏稳产期是亟需解决的问题。结合井口生产资料和储层水驱前缘波及系数对油藏模型进行历史拟合,建立了特低渗油藏剩余油的精细刻画模型,并综合利用静动态物理模拟实验、生产资料动态分析等方法,明确了特低渗油藏中高含水期剩余油成因及类型,据此提出了针对性的剩余油挖潜策略,最终在姬塬油田耿155区长1特低渗油藏进行了现场应用。研究结果表明,特低渗油藏剩余油主要分为储层平面和垂向非均质性导致的储层非均质型剩余油、局部储层注采不对应导致的注采不完善型剩余油以及储层黏土矿物运移膨胀导致的欠注型剩余油,针对性挖潜后目标井组采出程度提高5.1%~12.4%。经现场应用后,预测原油累计采出量相比原始措施提高15.6%~37.3%,为特低渗油藏中高含水期挖潜提供理论和技术支撑。

特高含水油藏开发后期深部调驱+二氧化碳吞吐技术

针对中高渗砂岩油藏进入特高含水开发后期,油藏优势渗流通道极其发育,常规控水稳油对策无法抑制含水持续升高的问题,利用深部调驱封堵优势渗流通道,改变液流方向,挖潜水淹路径绕流区剩余油,同时,利用CO_2吞吐降低原油流动性,提高井间驱油效率。研究结果表明:利用深部调驱+CO_2吞吐技术,可实现井间压力平衡,扩大驱替波及体积,达到降水增油的目的。该项技术在南堡凹陷Ng_1~2油藏实施1 a后,累计增油1.82×10~4t,含水降低12.4个百分点,采收率提高1.6个百分点。研究成果对特高含水油藏进一步提高采收率具有重要意义。

高浅北区稠油油藏空气泡沫驱实验

高浅北区稠油油藏平均地层温度65℃,原油地下黏度90.34 m Pa·s,已经历多次调剖调驱,含水已达97%。为了寻找提高采收率接替技术,进行了空气泡沫驱室内实验研究。微观模型驱油实验表明,泡沫驱的主要机理是封堵和乳化作用。在静态空气氧化实验中,该油藏原油可在模拟油藏条件下缓慢氧化,氧化速率为(2.261×10-5~2.448×10-5mol O2·h-1·[m L(oil)]-1,随压力、温度升高而增大。在物理模拟驱油实验中,在水驱采收率12.35%的基础上,依次进行的空气驱、空气泡沫驱、后续水驱、后续空气驱分别提高采收率36.47%、14.12%、11.18%、0;驱替过程中产出气中CO2和O2含量变化指明原油发生了氧化;注入压力变化指明空气泡沫的封堵作用。对于高浅北区稠油油藏,空气泡沫驱是可行的。

喇萨杏油田特高含水期厚油层微观剩余油分布

喇萨杏油田经过四十多年的注水开发与调整，已全面进入特高含水期开发阶段。由于微观孔隙结构不同，在厚油层中注入水波及区域内尚残存着大量剩余油，研究这部分剩余油的分布情况对提高厚油层采收率，改善水驱开发效果具有指导意义。利用铸体薄片、压汞资料、扫描电镜等资料研究了厚油层的微观孔隙特征。采取冷冻制片手段，避免常规样品制片方法破坏油水分布的初始状态的缺陷，使微观状态看得更清楚。利用荧光分析实验结果总结出特高含水期厚油层微观剩余油颗粒间油珠状、角隅状、喉道状，颗粒表面油膜状、吸附状以及颗粒内内孔状和裂隙状共3大类7种分布模式，对指导厚油层剩余油挖潜具有重要意义。

复杂断块特高含水油田储层及渗流规律研究

选取冀东复杂断块油田典型井岩心,采用水驱油实验与岩心分析相结合的方式,研究了特高含水阶段储层参数变化规律,并利用储层孔隙分形、油水相对渗透率及采液采油指数曲线分析了特高含水阶段的储层变化及油水渗流规律。研究结果表明:特高含水开发阶段储层孔隙度、渗透率均较原始状态有所增大,岩石亲水性逐渐增强,水相相对渗透率大幅度提高,无因次采液、采油指数均呈上升趋势,但无因次采液指数上升幅度明显高于无因次采油指数。

原位微乳液驱微观驱油实验研究

针对双河油田Ⅳ上层系高温、特高含水油藏条件,为提高剩余油开采程度,开展了基于阴-非离子与阴离子羧酸盐复配表面活性剂(B-1)和单芳烷基磺酸盐表面活性剂(A3-2)的原位微乳液驱油研究,分析对比了原位微乳液与表面活性剂/聚合物二元复合驱的驱油作用,利用高温高压微观可视化模拟系统,研究了原位微乳液驱过程中的剩余油启动及运移方式、驱替效果及微观驱油机理。研究结果表明,3%A3-2和3%B-1能形成超低界面张力(10^(-4)mN/m数量级),可与原油原位(即少量驱动力下)形成微乳液,增容参数大于20。A3-2溶液能与原油原位形成中相微乳液,B-1溶液能与原油原位形成下相微乳液。原位微乳液驱的驱油效果好于表面活性剂/聚合物二元复合驱。A3-2溶液的增溶能力好于B-1溶液,剩余油启动效果最好,微观驱油效果最佳。原位微乳液驱主要依靠表面活性剂的增溶作用,在多孔介质中与原油原位形成微乳液,从而达到混相驱油的作用效果;当原油在微乳液的胶束中增溶达到饱和时,进一步通过乳化携带、降低油水界面张力和改善润湿性等机理,优先启动簇状及斑状剩余油,使各种类型的剩余油都得到有效启动运移。

特高含水油藏复合驱技术提高采收率研究

针对双河油田IV5-11层系特高含水油藏条件,筛选出SP二元复合体系、ASP三元复合体系的优选配方,分别为2000 mg/表面活性剂SH6+1500 mg/L聚合物ZL-II和8000 mg/LNa_2CO_3+2000 mg/L表面活性剂SH6+1500mg/L聚合物ZL-II,并对比评价了两种体系的热稳定性能、多次吸附性能和岩心驱油效果。实验结果表明,在81℃、7.34 s^(-1)下优选出的SP二元体系、ASP三元体系的黏度分别为74.6mPa·s和46.5mPa·s,与原油间的界面张力分别为3.64×10^(-3)和3.89×10^(-4)mN/m,ASP三元体系与SP二元体系相比,界面张力有一个数量级的下降,黏度下降37%。81℃老化120 d后,APS三元体系的黏度保留率高于SP二元体系,界面张力始终维持在10^(-4)mN/m数量级,较SP二元体系低两个数量级,长期稳定性能优越于SP二元体系。ASP三元体系在与天然油砂重复接触5次以后,界面张力从3.63×10^(-4)mN/m增至4.67×10^(-3)mN/m,仍维持在超低数量级,且非均质岩心驱油效果整体比SP二元体系高3%~5%。因此采用三元复合驱技术作为双河油田IV5-11层系在特高含水阶段水驱后大幅度提高采收率的接替技术。经过两年的的矿场试验,区块已经见到较好的增油降水效果。

特高含水期三类油层剩余油分布与挖潜

针对XB油田油层平面上水淹面积大、纵向上层间水淹不均匀的状况,基于油层非均质性和井网特点,结合检查井资料,研究分析了剩余油在平面和纵向上的分布特点.同时指出剩余油分布主要是受储层非均质性和井网不完善影响,其中物性差型剩余油占整个剩余储量的1/3以上,并依据不同剩余油分布类型,确定了XB油田薄差油层压裂、酸化、层内细分注水、完善注采关系等精细挖潜对策.实践表明,通过分析流体渗流规律,结合剩余油分布情况及目前采油技术工艺水平,强化注采系统和注采结构调整,油田薄差储层动用状况显著改善,取得了较好挖潜效果.

特高含水油田常规开发动态指标预测方法分析

因为油田有相当一部分剩余可采储量将在特高含水期采出，所以如何将油田的剩余可采储量高效地在此阶段采出，是目前我国各油田急需解决的问题。解决此问题的基础就是对该阶段油田的开发动态指标进行准确的预测。针对特高含水油田的开发特点和面临的问题，结合油田常规开发动态指标预测方法的特征和实用性分析，对常规动态分析预测方法从机理和缺陷方面进行了评价，提出了在不考虑预测可靠性的前提下，适合该阶段的常规动态分析预测方法依次是油藏数值模拟法、预测模型法、递减规律法、联解法和水驱特征曲线法。指出了研究新的预测方法的必要，并指明了研究特高含水油田开发动态指标预测新方法的方向：支持向量机预测、基于时变系统的功能模拟预测、组合预测和智能预测。

中高渗透边水稠油油藏产液能力论证与应用

针对孤东油田某边水稠油油藏大幅度提液后综合含水率不增反降的现象,开展了中高渗透边水稠油油藏开发后期产液能力研究。基于渗流力学理论,利用流管法、物质平衡法等推导了边水稠油油藏油水两相渗流产能方程,分析了影响开发效果的主要因素;同时以垦东18-32区块的地质条件为基础建立概念模型,利用数值模拟技术研究了油藏开发后期产液能力适应条件及合理工作制度,形成了一套适用于边水稠油油藏产液能力的评价方法。结果表明:储层厚度、提液井到油水边界距离、井距和提液参数等是影响产液能力的关键因素。在目标区块进行矿场应用的11口井总增油量为2.47×10^(4) t,平均含水率增加0.2%,产出投入比达到3.5∶1。

胡状集油田特高含水油藏剩余油水驱技术

为对特高含水油藏深度挖潜,解决特高含水油藏层间矛盾和平面矛盾,提出了斜交夹层的识别方法,总结了斜交夹层下不同韵律层的水淹模式,研究了剩余油分布状况,并制定了相应的挖潜对策。同时,基于流线分布得出了微观过水倍数计算方法,根据计算结果可以通过改变水驱方向解决平面矛盾,增大水驱波及体积,挖潜平面剩余油。该方法在胡状集油田取得较好应用效果,证实了扇三角洲沉积存在斜交夹层,对剩余油形成和分布具有明显控制作用,过水倍数计算结果可从微观上表示水驱波及范围和强度。研究结果表明,斜交韵律层剩余油主要分布在2个夹层的上部,且逆向注水的波及系数和采收率略大于顺向注水,过水倍数是影响驱油效率和采收率的重要因素,过水倍数越大,水驱效果越好。胡状集油田斜交夹层剩余油研究和过水倍数计算方法的推导,为特高含水油藏挖潜提供了一种新的技术方法。

流固耦合理论在特高含水期油藏开发中的研究现状与发展趋势

在经过几十年的注水开収后,国内大多数油藏都迚入了特高含水期,这使得油藏的迚一步开采更加困难,尤其是经历了高压注水和循环注水等过程后,储层压力、地层孔隙结构和流体参数等不断的収生变化,这导致储层多孔介质収生不规律的变形,而这种变形同时也会影响地层流体的渗流作用,致使特高含水储层的流固耦合作用愈収明显。结合流固耦合理论在特高含水期油藏开収中的研究现状和収展历程迚行综述和分析,幵对该理论未来的収展趋势迚行展望。

彩9井区西山窑组特高含水油藏CO_(2)混相驱先导试验

目前彩南油田彩9井区西山窑组已进入高含水低产低能阶段,开井率仅为23.0%,即将面临废弃停产。为了提高该井区特高含水油藏产能,降低含水率,利用类比法、油藏工程及数值模拟方法,对彩9井区西山窑组油藏开展CO_(2)混相驱可行性论证及油藏工程设计,并进行先导试验。结果表明:先导试验区应选择小井距反七点井网的C2576井组,注入层位选择剩余油富集的J_(2)x_(1)^(2-2)小层,合理注入量为0.3倍孔隙体积(地面CO_(2)注入量为10500 t),注气速度为30~40 t/d,注采比为1.1~1.2。现场试验证实,该井组累计注入4529.7 t CO_(2)后,累计增油达到1269 t,CO_(2)换油率达到0.27 t/t,取得了较好的增产效果。该研究可为彩南油田CO_(2)混相驱扩大试验和全面调整开发提供技术支撑。

基于动态残余油饱和度表征的特高含水期油田数值模拟

长期水驱后驱油效率进一步提高、残余油饱和度不断下降,造成常规数值模拟在特高含水期含水率拟合误差大、指标预测精度低。开展了18组2000 PV水驱油实验,基于实验结果回归得到驱油效率变化规律,结合测井实验中束缚水饱和度与储层物性相关性结果,建立了考虑物性、原油黏度、驱替PV数的残余油饱和度定量表达式。利用Petrel RE平台及Intersect模拟器实现了残余油饱和度在数值模拟中的分区动态表征,提出增加关键井段饱和度作为历史拟合参数,实现了残余油饱和度的迭代修改。研究结果表明:驱替倍数从50 PV提高至2000 PV,驱油效率平均提高12.9个百分点;模型中过路井饱和度与测井解释结果更为吻合,单井拟合率达到90%以上。本文研究对油田进一步调整挖潜具有重要意义。

底水油藏特高含水期认识剩余油潜力的新方法

针对底水油藏进入特高含水期后,剩余油的潜力在油田开发后期调整挖潜过程中是至关重要的,提出了计算其剩余潜力的新方法。从底水油藏的过水倍数和驱油效率的定义出发,利用达西定律和物质平衡理论,推导出底水油藏过水倍数与驱油效率的关系式,提出采用拟合实际动态的遗传算法和正交试验设计方法求解关系式。通过实例表明,运用该方法可以找到油田特高含水期时的剩余油潜力,指导油田制定下一步调整挖潜方案。

渤海Q油田特高含水期水淹特征与剩余油挖潜

渤海Q油田为海上大型河流相砂岩油藏,进入特高含水期后,剩余油高度分散,低效井增多,稳产及低成本开发难度加大,探寻高效的挖潜方式对油田稳产及后续开发意义重大。在分析渤海Q油田开发存在的问题及制约瓶颈的基础上,对油田现有低效井进行了分类梳理,并根据钻井、测井、密闭取心、生产动态监测等资料剖析了油田特高含水期平面及纵向的水淹类型及特征,总结了剩余油富集模式。围绕低效井治理及剩余油高效挖潜,探索出集注采调整、措施改造、老井侧钻等多手段低效井治理与剩余油高效挖潜对策。相关措施在渤海Q油田不同类型油藏区块低效井的治理及剩余油的高效挖潜中得到了成功应用,油田综合含水稳定在93.7%,油田产量递减明显变缓。成果及方法为该油田特高含水期的低效井治理及高效挖潜探索出了一条有效途径,可供类似油藏高效挖潜借鉴。

渤海河流相底水稠油油藏特高含水期极限驱油效率认识

围绕渤海底水稠油油藏在特高含水阶段剩余油挖潜机理认识不清、渗流特征认识不深的难点问题,以典型河流相Q油田主力砂体为例,开展不同类型储层样品在2000 PV高倍数水驱下的极限水驱油效率实验研究。实验结果显示,在经过2000 PV高倍数水驱后,稀油、普1类稠油和普2类稠油的极限驱油效率分别为76.5%、75.5%和72.5%。在相同的高倍数水驱条件下,稀油样品驱油效率在100 PV处出现拐点,普1类稠油样品在300 PV处出现拐点,普2类稠油样品驱油效率在1000 PV处出现拐点。地层原油黏度越大,拐点出现的时机越晚,揭示水驱至残余油状态的废弃时机越晚。普2类稠油样品在100~1000 PV的高倍数驱替过程中,单位PV数下驱油效率要高于稀油样品和普1类稠油样品,在2000 PV的高倍数水驱条件下驱油效率最终可高达72.5%。实验结论可为底水稠油特高含水期大液量提液挖潜提供机理支撑。