Gas channeling control with an in-situ smart surfactant gel during water-alternating-CO_(2) enhanced oil recovery

Undesirable gas channeling always occurs along the high-permeability layers in heterogeneous oil reservoirs during water-alternating-CO_(2)(WAG)flooding,and conventional polymer gels used for blocking the“channeling”paths usually suffer from either low injectivity or poor gelation control.Herein,we for the first time developed an in-situ high-pressure CO_(2)-triggered gel system based on a smart surfactant,N-erucamidopropyl-N,N-dimethylamine(UC22AMPM),which was introduced into the aqueous slugs to control gas channeling inWAG processes.The water-like,low-viscosity UC22AMPM brine solution can be thickened by high-pressure CO_(2) owing to the formation of wormlike micelles(WLMs),as well as their growth and shear-induced structure buildup under shear flow.The thickening power can be further potentiated by the generation of denser WLMs resulting from either surfactant concentration augmentation or a certain range of heating,and can be impaired via pressurization above the critical pressure of CO_(2) because of its soaring solvent power.Core flooding tests using heterogeneous cores demonstrated that gas channeling was alleviated by plugging of high-capacity channels due to the in-situ gelation of UC22AMPM slugs upon their reaction with the pre-or post-injected CO_(2) slugs under shear flow,thereupon driving chase fluids into unrecovered low-permeability areas and producing an 8.0% higher oil recovery factor than the conventional WAG mode.This smart surfactant enabled high injectivity and satisfactory gelation control,attributable to low initial viscosity and the combined properties of one component and CO_(2)-triggered gelation,respectively.This work could provide a guide towards designing gels for reducing CO_(2) spillover and reinforcing the CO_(2) sequestration effect during CO_(2) enhanced oil recovery processes.

中深层稠油水平井前置CO_(2)蓄能压裂技术

利用准噶尔盆地西北缘乌夏地区中深层稠油油藏参数,对水平井前置CO_(2)蓄能压裂技术的开发机理、关键操作参数及开发效果进行了详细研究。研究结果表明:①伴随压裂—焖井—生产等开发阶段的延伸,前置CO_(2)蓄能压裂后的油井逐步显现出增能改造、扩散降黏、膨胀补能、释压成泡沫油流等特性,井底流压提高了2~4MPa,CO_(2)扩散至油藏的1/3,原油黏度降至500mPa·s以下,泡沫油流明显;②研究区最优压裂段间距为60m、裂缝半长为90m、裂缝导流能力为10t/m,CO_(2)最佳注入强度为1.5m3/m,注入速度为1.8m3/min,油井焖井时间为30d,油藏采收率提高了2%~3%;③通过与常规压裂生产效果进行对比,前置CO_(2)蓄能压裂技术可使产油量提高5.2t/d,预测CO_(2)换油率达2.45,开发效果显著提升。

适合致密油藏的超临界CO_(2)-气溶性表面活性剂复合吞吐技术

为了进一步提高致密油储层超临界CO_(2)吞吐的开发效果,探索适合致密油藏的超临界CO_(2)-气溶性表面活性剂复合吞吐技术,通过原油黏度实验、油气界面张力实验、最小混相压力实验、原油膨胀系数实验以及超临界CO_(2)-气溶性表面活性剂复合吞吐模拟实验,评价了不同类型气溶性表面活性剂的性能及其对吞吐采收率的影响。结果表明:气溶性表面活性剂GRS⁃1的综合性能更加突出,随着气溶性表面活性剂质量分数的不断增大,原油黏度、油气界面张力和最小混相压力均呈现出逐渐降低的趋势,而原油体积膨胀系数则逐渐增大,并且岩心的吞吐采收率和入口端压力也呈现出逐渐增大的趋势;随着混合流体注入量的增加以及闷井时间的延长,岩心吞吐采收率和入口端压力均逐渐增大,并且岩心的渗透率越大,吞吐采收率就越高;超临界CO_(2)-气溶性表面活性剂复合吞吐的最佳实验参数为气溶性表面活性剂GRS⁃1的质量分数0.6%、混合流体注入量0.5 PV、闷井时间3 h、吞吐轮次3次。该复合吞吐技术能够显著提高致密油藏的采收率,对高效开发致密油藏具有指导意义。

低渗砂岩油田CO_(2)驱化学机理及提高采收率研究

针对低渗砂岩油藏进行了CO_(2)驱开发技术研究,分析了CO_(2)驱油化学机理及主要影响因素。基于目标油藏流体特征进行了PVT拟合,确定其CO_(2)驱最小混相压力,明确了不同压力及注入时机对CO_(2)驱采收率、气油比、含水率及驱动压差等的影响规律,探究了CO_(2)泡沫驱在提高采收率方面的效用。结果表明:24.5 MPa为目标区域CO_(2)驱的最小混相压力,采收率会随着压力的升高而增加,28 MPa时CO_(2)驱提高采收率可达30.57%。气体突破时间、总采收率与CO_(2)注入时机密切相关,CO_(2)注入越早,越有利于采收率的提高,出口含水率为60%时注入可提高采收率39.13%。CO_(2)泡沫驱可以在一定程度上起到提高采收率的效用。

页岩油藏注CO_(2)驱孔隙动用特征研究

CO_(2)在页岩油藏驱油时的孔隙动用特征是评价其应用于提高页岩油藏采收率效果的一项重要指标。因此,开展了超临界CO_(2)驱替页岩岩心室内实验,并以核磁共振(NMR)在线岩心扫描技术为手段对CO_(2)驱页岩油藏的孔隙动用特征和规律进行研究。结果表明,超临界CO_(2)非混相驱油主要动用页岩中孔隙半径在0.1~3.0µm范围内的油,而此过程中小于0.008µm孔隙半径内的油量反而增加,分析原因主要是CO_(2)在页岩层中通过压差和扩散作用将大孔隙内页岩油带入小孔隙中并发生吸附滞留,在驱替时间5 h后,CO_(2)驱替页岩油采收率达到35.7%,驱油效果较好。

苏北盆地江苏油田CO_(2)驱油技术进展及应用

CCUS(碳捕集、利用与封存)技术对绿色低碳转型、实现“双碳”目标意义重大,而CO_(2)驱油埋存是其重要内容。苏北盆地江苏油田针对复杂断块油藏提高采收率的技术瓶颈开展CO_(2)驱油技术攻关及多种类型矿场试验,形成了以重力稳定驱、驱吐协同等为特点的复杂断块油藏CO_(2)驱油的4种差异化模式,成功开展了花26断块“仿水平井”重力稳定驱等技术先导试验,建成了10×10^(4) t的复杂断块油藏CCUS示范工程。江苏油田累计注入液碳量30.34×10^(4) t,累计增油量9.83×10^(4) t,实现了较好的增产效果及经济效益。技术研究及试验可为其他复杂断块油藏的CO_(2)驱开发提供参考借鉴。

CO_(2)捕集、利用和封存在能源行业的应用:全球案例分析和启示

为了实现中国21世纪中叶达到碳中和,大规模应用CO_(2)捕获、利用和封存(CCUS)技术可以减少能源行业的温室气体排放。通过对国内外CCUS技术、项目的调研,得出了关于未来CCUS部署的3个见解,这些见解有助于能源行业实现转型。首先,碳源浓度较低导致碳捕集效率低,从而导致碳捕集的经济成本较高的问题是目前CCUS项目无法商业化的主要因素,在发展当前的碳捕集技术,提高捕集效率和降低捕集成本的同时也应大力研究空气捕集技术,尤其是在工艺设计和新型吸附材料研发方面,争取实现弯道超车;其次,CO_(2)在油气藏和咸水层的封存与利用应当作为CCUS技术研究的重点,逐步实现大规模推广,并在技术升级和体系完善的基础上推广CO_(2)增强地热、煤层气等其他耦合技术;最后,应当在当前国际上较成熟的碳政策的基础上研究适合中国的激励政策,建立有效的法律法规。论文总结了当前CCUS的关键挑战,并为未来的CCUS研究方向提供了指导方向。

准噶尔盆地吉木萨尔凹陷页岩油藏注CO_(2)吞吐提高采收率机理

页岩油藏的成功开发在缓解我国能源紧缺的问题上发挥了重要作用,但衰竭式开发采收率较低,传统提高采收率的措施难以有效增产,因此明确页岩油藏注CO_(2)提高采收率的机理,对于探索页岩油的开发技术具有重要意义。为此,以准噶尔盆地吉木萨尔凹陷页岩油藏为例,开展了一系列注CO_(2)实验并结合流体注入能力和油气组分传质评价实验,揭示了注CO_(2)吞吐提高采收率的机理,并明确了注CO_(2)吞吐的埋存形式、埋存效率与其生产动态之间的耦合关系。研究结果表明:①CO_(2)的注入能力是水的7.77倍、N2的1.18倍;增加注入压力,促进CO_(2)与原油之间的相互作用,能有效提高CO_(2)的注入能力。②CO_(2)对原油物性的改善能力显著强于N2,在CO_(2)—原油组分传质的协同作用下,注CO_(2)吞吐的采收率比N2高6.84%。③原油膨胀和黏度降低是注CO_(2)吞吐前期提高采收率的主要机制,而后期主要通过CO_(2)对原油轻质烃类组分置换、萃取进一步实现了采收率的提高,混相压力(MMP)是注CO_(2)吞吐的阈值压力。④注CO_(2)吞吐过程中,埋存率从最初的77.77%持续降低到7.14%,不同形式CO_(2)的埋存比例具有动态变化的特征,但主要以游离态和溶解态埋存为主。结论认为,吉木萨尔凹陷页岩油藏注CO_(2)吞吐在提高采收率的同时实现了CO_(2)的埋存,实验结果为研究国内相似页岩油藏注CO_(2)吞吐提采—埋存效率提供理论支撑和经验借鉴。

CO_(2)驱不同注入方式对低渗透储层渗流能力的影响

CO_(2)驱是提高低渗透储层采收率有效的技术手段。CO_(2)与原油接触后使体系中的沥青质以固体形式沉积下来,对储层造成一定堵塞,但同时发生的溶蚀作用整体上提高了储层渗流能力,且不同注入方式下CO_(2)驱对低渗透储层渗流能力的影响具有一定差异。开展了CO_(2)连续注入及CO_(2)-水交替注入后有机垢堵塞机理实验、储层润湿性实验及CO_(2)-水溶液对岩石的溶蚀评价实验,并对相对渗透率曲线参数变化特征进行评价,定量表征了CO_(2)驱不同注入方式对低渗透储层渗流能力的影响程度。结果表明:CO_(2)驱产生的有机垢会对岩石孔喉造成堵塞,但整体上CO_(2)与绿泥石反应导致的溶蚀作用更强,使得低渗透储层采收率有效提高;且CO_(2)-水交替注入比CO_(2)连续注入引起的有机垢堵塞要弱,溶蚀作用效果更好,渗透率损失率更低,能够在中、大孔隙中取得更好的驱油效果,整体上更能增大岩石孔隙空间和渗流通道,使得低渗透储层采收率有效提高。

致密油藏注CO_(2)防窜体系研究进展

致密油藏注CO_(2)不仅可以实现增压、混溶、降黏等目的,也是CO_(2)就地埋存和高效利用的重要途径。受CO_(2)与原油流度差异,特别是储层非均质性的影响,致密油藏注CO_(2)极易沿优势通道(裂缝)窜逸,因此,CO_(2)防窜是实现CO_(2)埋存和高效排驱的关键。通过对致密油注CO_(2)防窜体系的国内外研究动态进行综述,对比评述了凝胶、聚合物、泡沫、表面活性剂的防窜机理,重点概述了CO_(2)响应性表面活性剂的类型、CO_(2)响应特征及智能暂堵机制,在此基础上对致密油注CO_(2)防窜体系的应用前景进行了展望。依据现阶段CO_(2)响应性表面活性剂在CO_(2)防窜体系的应用,提出了CO_(2)响应性表面活性剂在CO_(2)防窜体系的重点研究方向:①设计和研发具备超临界CO_(2)可溶性,开关乳液、囊泡、凝胶、“蠕虫状”胶束自组装及原油触发解组装3方面特点的CO_(2)响应性表面活性剂;②CO_(2)响应性表面活性剂在致密储层的渗流规律、对裂缝的封堵机制、原油触发的解堵机理等系列科学问题亟需系统性探讨和深入研究。

CO_(2)混相驱胶质、沥青质析出规律——以东河6油藏为例

掌握油田原油在注CO_(2)过程中是否混相及油层沥青质的沉淀规律具有重要意义。设计了一套高温、高压混相及沉淀实验装置,并开展CO_(2)混相驱胶质、沥青质析出规律的实验研究,模拟东河6油藏注气开采过程,判断注入气体与地层流体是否达到混相,表征油层内胶质、沥青质的析出规律。实验结果表明:东河6油藏注CO_(2)驱提采机理为一次混相;沥青质相对沉淀量随CO_(2)注入比例的增加而迅速增加后又缓慢减少,胶质相对沉淀量随注入比例的增加先降低后增加;注CO_(2)后降压衰竭开采优先采出饱和烃,油层原油沥青质含量迅速增加。东河6油藏注CO_(2)驱保持最低混相压力45.4 MPa以上开采,可提高驱替效率,减少开采过程中胶质、沥青质的析出,提高原油采收率。研究结果可为注CO_(2)油藏提供一种混相压力及沥青质沉淀测定的方法,支撑注CO_(2)油藏开发方案的制定。

海上低渗油藏CO_(2)混相驱可行性实验研究

海上珠江口盆地陆丰凹陷低渗、特低渗储量丰富,水驱开发难度大,注气开发需求迫切。CO_(2)驱是提高采收率的主要技术之一,但目前海上CO_(2)综合利用方面应用较少。以陆丰凹陷L油藏为例,开展了目标油藏原油注CO_(2)驱油机理实验和长岩心CO_(2)驱油效果评价实验,重点对比CO_(2)注入前后原油相态特征的变化,并对不同开发方式驱油效果进行了对比优化研究,为目标油田CO_(2)驱可行性提供依据。实验结果表明,CO_(2)可以有效提高低渗油藏的开发效果,提高采收率幅度可以在水驱的基础上提高11.75%,交替驱可以作为后期注CO_(2)防窜和进一步提高采收率的技术手段。实验研究结果对海上低渗油藏CO_(2)注气开发提供技术支持。

致密油藏CO_(2)吞吐驱油和封存注采参数敏感性分析——以鄂尔多斯盆地延长组长7段致密油藏典型储集层为例

致密油藏CO_(2)吞吐开发具有提高原油采收率和封存CO_(2)的双重效果。目前,对致密油藏CO_(2)吞吐驱油和封存研究中,鲜有学者将CO_(2)封存量相关参数作为评价指标。以鄂尔多斯盆地延长组长7段某致密油藏典型储集层为例,利用数值模拟技术分别选取吞吐时机、注气速度、注气时间、焖井时间、生产时间和吞吐轮次为注采参数,以换油率、CO_(2)滞留系数及驱油-封存协同综合系数为评价指标,采用单因素控制变量法和多因素正交试验设计,结合极差分析方法,分析了6个注采参数对3个评价指标的敏感性。结果表明:当注重CO_(2)驱油时,建议注气时间为30~60 d,注气速度为0.001 0~0.003 0 PV/d,吞吐时机小于0.5年;当注重CO_(2)封存时,建议生产时间为30~230 d,注气速度为0.0075~0.010 0 PV/d,注气时间为145~180 d;当CO_(2)驱油和封存协同优化时,建议注气时间为30~65 d,吞吐时机为6个月前,焖井时间为10~20 d。

新疆油田中深层稠油CO_(2)驱/吞吐实验研究

针对新疆油田中深层稠油油藏的“中等偏强—强”速敏伤害以及“强—极强”水敏伤害引起的注水开发效果不理想的问题,基于CO_(2)独特的物理和化学性质,借助高温高压PVT实验仪和长岩心驱替装置,开展CO_(2)-原油高压物性测定和CO_(2)驱/吞吐提高采收率可行性研究,结合气相色谱和高温高压流变仪表征产出油的组成及黏度变化。实验结果表明,57.345%摩尔分数的CO_(2)能将溶解气油比(GOR)从32 m^(3)/m^(3)增大至149.3 m^(3)/m^(3)、泡点压力(pb)从6.8 MPa增大至15.7 MPa,原油体积系数从1.06增大至1.27,原油密度从0.8965 g/cm^(3)降低至0.8548 g/cm^(3),原油黏度从419.3 mPa·s降低至253.4 mPa·s,因此CO_(2)能有效补充地层能量,增大原油弹性能,减小渗流阻力。第一轮次0.95 PV(孔隙体积)的CO_(2)驱的原油采出程度为32.8%,焖井24 h后多孔介质中的流体重新分布,第二轮次0.5 PV的CO_(2)驱能提高原油采出程度17.9%。而5轮次CO_(2)吞吐的原油采出程度为63.5%。产出油的黏度呈降低的趋势,主要原因是原油中的沥青质在多孔介质中发生沉积。实验结果明确了CO_(2)驱/吞吐在新疆油田中深层稠油提高采收率的可行性。

多孔介质中CO_(2)埋存机理物理模拟实验评价

为了弄清高温高压多孔介质中CO_(2)的埋存机理,采用室内物理模型,对多孔介质中CO_(2)埋存机理进行了物理模拟实验评价。结果表明,CO_(2)溶解埋存主要受温度、压力和地层水矿化度的影响;CO_(2)溶于地层水后与岩石中的矿物发生矿化反应,反应前后岩石矿物质量分数发生显著变化;气水交替驱可有效地延缓CO_(2)的突破,提高CO_(2)埋存率,从而提高原油采收率。

CO_(2)对稠油油藏的物性调控及辅助蒸汽驱提高采收率

为提高稠油油藏蒸汽驱后期开发效率,聚焦“双碳”背景下CCUS-EOR(碳捕集利用和封存体系提高采收率)技术的应用,以克拉玛依油田J6区为研究对象,通过对CO_(2)作用前后的稠油四组分分析,测试饱和压力、膨胀系数、黏度和密度变化情况,探究CO_(2)对稠油物性的调控效果;通过并联岩心物理模拟实验研究CO_(2)辅助蒸汽驱提高采收率效果。研究结果表明:稠油黏度主要受胶质和沥青质含量影响,稠油随着CO_(2)溶解气量的增加,饱和压力由2.08 MPa上升至11.11 MPa,膨胀系数总体呈上升趋势,上升7.6%;同时,黏度降低30.5%,密度减小3.5%。表明CO_(2)在提高饱和压力的同时,通过优化膨胀系数、黏度和密度,有效改善了稠油物性。此外,采用CO_(2)辅助蒸汽驱后,在CO_(2)溶解降黏、破乳的作用下,稠油采收率从38.55%提高至46.46%,相比纯蒸汽驱提高了7.91%。为CO_(2)辅助蒸汽驱提高稠油采收率的应用提供了理论和实验基础,可为同类型稠油油藏提高采收率提供借鉴。

Further discussion of CO_(2) huff-n-puff mechanisms in tight oil reservoirs based on NMR monitored fluids spatial distributions

Due to the poor physical properties of tight reservoirs,CO_(2) huff-n-puff(HNP)is considered a potential enhanced oil recovery(EOR)method after primary depletion.Optimization plays a critical role in the effective implementation of CO_(2) huff-n-puff.But the optimization requires a good understanding of the EOR mechanisms.In this work,the spatial distribution of oil saturation under different experimental conditions was analyzed by the NMR method to further discuss the HNP mechanisms.According to the variation of 1D frequency signal amplitude,we divided the core into the hardly movable area and movable area,the region with the obvious signal decline was defined as the movable area,and the hardly movable area was the region with limited signal decline.Based on that the recovery characteristics of different scenarios were evaluated.Firstly,the necessity of the soaking stage was studied,where three scenarios with different soaking times were carried out.Secondly,the injection pressure was adjusted to investigate the effect of the pressure gradient.The T_(2) spectra show that soaking has significantly improved the production of crude oil in small pores,and higher oil recovery in a single cycle is observed,but it is lower when the elapsed time(total operation time)is the same.31.03% of oil can be recovered after 3 cycles HNP,which increases to 33.8% and 37.06% for the 4 cycles and 6 cycles cases.As the pressure gradient increases,more oil is removed out of the matrix,and the oil in the deep part of the reservoir can be effectively recovered.During the CO_(2) huff-n-puff process,the oil distributions are similar to the solution gas drive,the residual oil is distributed at the close end of the core and the range that the oil can be efficiently recovered is limited.

Reservoir heterogeneity controls of CO_(2)-EOR and storage potentials in residual oil zones:Insights from numerical simulations

Residual oil zones(ROZs)have large potential for CO_(2)enhanced oil recovery(EOR)and geologic storage.During CO_(2)injection,the migration of CO_(2)in ROZs controls the performance of both EOR and storage.However,it has not been clearly visualized and understood that how geological heterogeneity factors control the transport of CO_(2)in ROZs.In this study,the oil recovery performance and geologic storage potential during continuous CO_(2)injection in a representative ROZ are studied based on geostatistical modelling and high-fidelity three-phase flow simulation.We examined the influence of autocorrelation length of permeability,global heterogeneity(DykstraeParsons coefficient),and permeability anisotropy on cumulative oil recovery and CO_(2)retention fraction.Simulation results indicate that,as the permeability autocorrelation length increases,the cumulative oil recovery and CO_(2)storage efficiency decrease.This results from the accelerated migration of CO_(2)along high permeability zones(i.e.,gas channeling).The increase in global heterogeneity and permeability anisotropies can lead to low oil recovery and poor CO_(2)sequestration performance,depending on the degree of CO_(2)channeling.The net utilization ratio of CO_(2)(CO_(2)retained/oil produced)unfavorably increases with both autocorrelation length and Dykstra eParsons coefficient,but decreases with the increase in kv/kh.Such a decrease is attributed to enlarged swept volume induced by gravity override.The study provides important implications for fieldscale CO_(2)EOR and storage applications in ROZs.

CO_(2)驱后水气交替注入驱替特征及剩余油启动机制

水气交替注入(WAG)是特低渗透油藏提高采收率的有效手段之一,但在CO_(2)连续气驱后实施WAG驱,仍然存在驱替特征模糊、剩余油启动机制不明确等问题。以海拉尔油田贝14区块为研究对象,借助Micro⁃CT研究WAG驱启动剩余油的微观作用机制,同时通过长岩心驱替实验研究CO_(2)驱后水气交替注入的驱替特征。Micro⁃CT实验结果表明:目标区块大孔隙的体积比例超过85%,在被CO_(2)全部动用后成为了气窜通道,采收率仅47.95%;CO_(2)驱后WAG驱不仅启动次级大孔隙中的剩余油,对中小孔隙的剩余油也有不同程度的动用。长岩心实验结果表明:在CO_(2)驱后开展WAG驱,水和气段塞需要交替注入一定量(0.40 PV左右)后采收率才能大幅度增加,气水比和段塞尺寸存在最优值,分别为1∶1和0.10 PV,该条件下WAG驱的采收率增幅主要由第3、4交替轮次所贡献,10轮次的水气交替注入可在CO_(2)驱的基础上提高采收率18.68百分点。研究成果可为特低渗透油藏CO_(2)驱后进一步提高采收率提供理论支撑。

Nuclear magnetic resonance experimental study of CO_(2) injection to enhance shale oil recovery

Factors affecting CO_(2) flooding of shale oil reservoir were studied by nuclear magnetic resonance(NMR) experiments, the effects of time, pressure, temperature on the recovery of CO_(2) flooding in shale oil reservoir were analyzed based on nuclear magnetic resonance T2 spectrum, and the effect of fracture development degree on recovery of CO_(2) flooding in shale oil reservoir was analyzed based on NMR images. In the process of CO_(2) flooding, the recovery degree of the shale oil reservoir gradually increases with time. With the rise of pressure, the recovery degree of the shale oil reservoir goes up gradually. With the rise of temperature, the recovery degree of shale oil increases first and then decreases gradually. For CO_(2) flooding in matrix core, the crude oil around the core surface is produced in the initial stage, with recovery degree going up rapidly;with the ongoing of CO_(2) injection, the CO_(2) gradually diffuses into the inside of core to produce the oil, and the increase of recovery degree slows down gradually. For CO_(2) flooding in matrix core with fractures, in the initial stage, the oil in and around the fractures are produced first, and the recovery degree goes up fast;with the extension of CO_(2) injection time, CO_(2) diffuses into the inside of the core from the fractures and the core surface to produce the oil inside the core, and the increase of recovery degree gradually slows down. Fractures increase the contact area between injected CO_(2) and crude oil, and the more the fractures and the greater the evaluation index of fractures, the greater the recovery degree of shale oil will be.