Experimental study of the effects of a multistage pore-throat structure on the seepage characteristics of sandstones in the Beibuwan Basin:Insights into the flooding mode

To investigate the relationship between grain sizes, seepage capacity, and oil-displacement efficiency in the Liushagang Formation of the Beibuwan Basin, this study identifies the multistage pore-throat structure as a crucial factor through a comparison of oil displacement in microscopic pore-throat experiments. The two-phase flow evaluation method based on the Li-Horne model is utilized to effectively characterize and quantify the seepage characteristics of different reservoirs, closely relating them to the distribution of microscopic pores and throats. It is observed that conglomerate sandstones at different stages exhibit significant heterogeneity and noticeable differences in seepage capacity, highlighting the crucial role played by certain large pore throats in determining seepage capacity and oil displacement efficiency. Furthermore, it was found that the displacement effects of conglomeratic sandstones with strong heterogeneity were inferior to those of conventional homogeneous sandstone, as evidenced by multiple displacement experiments conducted on core samples with varying granularities and flooding systems. Subsequently, core-based experiments on associated gas flooding after water flooding were conducted to address the challenge of achieving satisfactory results in a single displacement mode for reservoirs with significant heterogeneity. The results indicate that the oil recovery rates for associated gas flooding after water flooding increased by 7.3%-16.4% compared with water flooding alone at a gas-oil ratio of approximately 7000 m^(3)/m^(3). Therefore, considering the advantages of gas flooding in terms of seepage capacity, oil exchange ratio, and the potential for two-phase production, gas flooding is recommended as an energy supplement mode for homogeneous reservoirs in the presence of sufficient gas source and appropriate tectonic angle. On the other hand, associated gas flooding after water flooding is suggested to achieve a more favorable development effect compared to a single mode of energy supplementation for strongly heterogeneous sandstone reservoirs.

An experimental and numerical study of chemically enhanced water alternating gas injection

In this work, an experimental study combined with numerical simulation was conducted to investigate the potential of chemically enhanced water alternating gas （CWAG） injection as a new enhanced oil recovery method. The unique feature of this new method is that it uses alkaline, surfactant, and polymer additives as a chemical slug which is injected during the water alternating gas （WAG） process to reduce the interfacial tension （IFT） and simultaneously improve the mobility ratio. In essence, the proposed CWAG process involves a combination of chemical flooding and immiscible carbon dioxide （CO2） injection and helps in IFT reduction, water blocking reduction, mobility control, oil swelling, and oil viscosity reduction due to CO2 dissolution. Its performance was compared with the conventional immiscible water alter- nating gas （I-WAG） flooding. Oil recovery utilizing CWAG was better by 26 % of the remaining oil in place after waterflooding compared to the recovery using WAG conducted under similar conditions. The coreflood data （cumulative oil and water production） were history mat- ched via a commercial simulator by adjusting the relative permeability curves and assigning the values of the rock and fluid properties such as porosity, permeability, and the experimentally determined IFT data. History matching ofthe coreflood model helped us optimize the experiments and was useful in determining the importance of the parameters influencing sweep efficiency in the CWAG process. The effectiveness of the CWAG process in pro- viding enhancement of displacement efficiency is evident in the oil recovery and pressure response observed in the coreflood. The results of sensitivity analysis on CWAG slug patterns show that the alkaline-surfactant-polymer injection is more beneficial after CO2 slug injection due to oil swelling and viscosity reduction. The CO2 slug size analysis shows that there is an optimum CO2 slug size, around 25 % pore volume which leads to a maximum oil recovery in the CWAG process. This study shows that the ultralow IFT system, i.e., IFT equaling 10 2 or 10 3 mN/ m, is a very important parameter in CWAG process since the water blocking effect can be minimized.

Field Scale Simulation Study of Miscible Water Alternating CO₂Injection Process in Fractured Reservoirs

Vast amounts of world oil reservoirs are in natural fractured reservoirs. There are different methods for increasing recovery from fractured reservoirs. Miscible injection of water alternating CO2?is a good choice among EOR methods. In this method, water and CO2?slugs are injected alternatively in reservoir as miscible agent into reservoir. This paper studies water injection scenario and miscible injection of water and CO2?in a two dimensional, inhomogeneous fractured reservoir. The results show that miscible water alternating CO2?gas injection leads to 3.95% increase in final oil recovery and total water production decrease of 3.89% comparing to water injection scenario.

Evaluation of sour gas-low salinity waterflooding in carbonate reservoirs-A numerical simulation approach

Although significant amount of H_(2)S(sour gas)rich natural gas is estimated globally,but not much attention has been given to the application of H_(2)S in the oil recovery process.Recent studies on the use of H_(2)S in oil recovery processes showed that H_(2)S has the potential of improving the oil recovery,and it can be even more effective than using CO_(2) in some processes.H_(2)S can equally dissolve in the water,react with the reservoir rock to change its surface charge,porosity,and permeability.However,previous in-vestigations on H_(2)S oil recovery attributed the improved oil recoveries to the higher miscibility of H_(2)S in the oil,and the reduction in the oil viscosity.Therefore,there is limited understanding on the H_(2)S-oil-brine-rock geochemical interactions,and how they impact the oil recovery process.This study aims to investigate the interactions between H_(2)S,oil,and carbonate formations,and to assess how the combi-nation of H_(2)S and low salinity water can impact the wettability and porosity of the reservoirs.A triple layer surface complexation model was used to understand the influence of key parameters(e.g.,pressure,brine salinity,and composition)on the H_(2)S-brine-oil-rock interactions.Moreover,the effects of mineral content of the carbonate rock on H_(2)S interactions were studied.Thereafter,the results of the H_(2)S-oil-brine-rock interactions were compared with a study where CO_(2) was used as the injected gas.Results of the study showed that the seawater and its diluted forms yielded identicalζ-potential values of about 3.31 mV at a pH of 3.24.This indicates that at very low pH condition,pH controls the ζ-potential of the oil-brine interface regardless of the brine's ionic strength.The study further demonstrated that the presence of other minerals in the carbonate rock greatly reduced the calcite dissolution.For instance,the calcite dissolution was reduced by 4.5%when anhydrite mineral was present in the carbonate rock.Findings from the simulation also indicated that CO_(2) produced negative ζ-potential values for the car-bonate rocks,and these values were reduced by 18.4%-20% when H_(2)S was used as the gas phase.This implies that the H_(2)S shifted the carbonate rockζ-potentials towards positive.The outcomes of this study can be applied when designing CO_(2) flooding and CO_(2) storage where the gas stream contains H_(2)S gas since H_(2)S greatly influences the dissolution of the carbonate mineral.

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。

不同灌溉模式下水稻田氮素运移规律

为了提高水稻田氮素利用率减少农业面源污染,选取了2块大田,分别采取干湿交替节水灌溉和传统淹灌方式,分析稻田土壤剖面NH_(4)^(+)-N、NO_(3)^(-)-N及TN浓度的分布规律。结果表明节水灌溉和传统淹灌条件下,施入3次氮肥后,地表水及土壤不同深度处NH_(4)^(+)-N和TN浓度变化规律相似且均会出现峰值后迅速降低。而节水灌溉条件下由于NO_(3)^(-)-N浓度太低导致峰值不明显,传统淹灌条件下的NO_(3)^(-)-N浓度峰值到达时间相比于NH_(4)^(+)-N有一定滞后性。整体来说,水稻田施肥后5 d内是防控田间氮素流失的关键时期;节水灌溉条件下水稻田的灌溉水利用效率和氮素生产率更高。此研究结果可为提高水肥利用率和减少农业面源污染等提供理论依据。

旱涝急转条件下水稻水分利用效率变化研究

为探究水稻在旱涝急转条件下光合效率及水分利用变化规律,从而为研究水稻经历旱涝急转灾害后产量变化及灌溉方式提供科学依据,以Ⅱ优898水稻为研究对象,采用四因素三水平正交实验,研究了旱涝急转条件下,水稻叶片水分利用效率WUE_(leaf)及气孔导度gs、蒸腾速率E、光合速率A等参数的变化。结果表明干旱程度和淹水深度对光合作用的累积作用最明显;A/gs与叶气温差呈线性相关,但旱涝急转导致响应积极性降低;分蘖期末~拔节孕穗期初WUE_(leaf)~g_(s)均可用上凸抛物线描述,此阶段干旱引起绝对光合速率的降低是影响生育期生物量积累的控制因素。拔节孕穗中后期WUE_(leaf)~g_(s)均可用下凸抛物线描述,经历旱涝急转导致叶片提前衰老,绝对蒸腾速率下降,WUE_(leaf)的增加并不能促使产量的补偿,可提前控制土壤含水量,减少非必要的水资源消耗。

延长低渗透油藏CO_(2)驱油参数优化数值模拟研究

CO_(2)驱油在特低渗油藏中具有较好的应用效果,是提高采收率的重要方法。以延长油田H区块为研究对象,分析目前注水开发存在的问题,根据动静态参数将井组分成2类,应用数值模拟方法,分别对2类井组CO_(2)驱油的开发方式、注气时机、注气速度、井底流压及气水交替周期进行了优化。结果表明,以气水比1∶1且气水交替的方式在油井含水40%~60%时注气效果最佳。第1类注气井组的最优注气速度为10~15 t/d,井底流压1 MPa,气水交替周期60天;第2类注气井组最优注气速度为5~10 t/d,井底流压2 MPa,气水交替周期30天。该研究结果对H区块低渗油藏现场注CO_(2)驱油设计具有重要的指导作用。

Research progress and potential of new enhanced oil recovery methods in oilfield development

This paper reviews the basic research means for oilfield development and also the researches and tests of enhanced oil recovery(EOR)methods for mature oilfields and continental shale oil development,analyzes the problems of EOR methods,and proposes the relevant research prospects.The basic research means for oilfield development include in-situ acquisition of formation rock/fluid samples and non-destructive testing.The EOR methods for conventional and shale oil development are classified as improved water flooding(e.g.nano-water flooding),chemical flooding(e.g.low-concentration middle-phase micro-emulsion flooding),gas flooding(e.g.micro/nano bubble flooding),thermal recovery(e.g.air injection thermal-aided miscible flooding),and multi-cluster uniform fracturing/water-free fracturing,which are discussed in this paper for their mechanisms,approaches,and key technique researches and field tests.These methods have been studied with remarkable progress,and some achieved ideal results in field tests.Nonetheless,some problems still exist,such as inadequate research on mechanisms,imperfect matching technologies,and incomplete industrial chains.It is proposed to further strengthen the basic researches and expand the field tests,thereby driving the formation,promotion and application of new technologies.

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。

Simulation of gas production from hydrate reservoir by the combination of warm water flooding and depressurization

Gas production from hydrate reservoir by the combination of warm water flooding and depressurization is proposed,which can overcome the deficiency of single production method.Based on the combination production method,the physical and mathematical models are developed to simulate the hydrate dissociation.The mathematical model can be used to analyze the effects of the flow of multiphase fluid,the kinetic process of hydrate dissociation,the endothermic process of hydrate dissociation,ice-water phase equilibrium,the convection and conduction on the hydrate dissociation and gas and water production.The mechanism of gas production by the combination of warm water flooding and depressurization is revealed by the numerical simulation.The evolutions of such physical variables as pressure,temperature,saturations and gas and water rates are analyzed.Numerical results show that under certain conditions the combination method has the advantage of longer stable period of high gas rate than the single producing method.

旱涝交替下驮英灌区年内水资源优化调控研究

针对旱涝频发下区域水资源分配不均问题,基于某时段可供水量是否满足用户层理想需水量,提出旱涝交替下年内水资源优化调控方法。以驮英灌区为研究对象,建立水资源优化调控模型,通过2030规划水平年驮英灌区供水侧供水能力分析及需水侧水资源需求预测,分析远期水资源供需平衡情况,研究年内尺度的水资源优化调控方案。结果表明,规划水平年总缺水1692万m^(3),年缺水率较调控前降低37.7%,生活用水得到充分保证,有效缓解了水资源短缺和分配不均局面。研究成果可为驮英灌区旱涝交替水资源优化调控提供决策方案,且该方法可供旱涝频发区域水资源优化调控参考。

姬塬油田黄3区长8超低渗油层CO_(2)驱埋实验

为明确姬塬油田超低渗油藏CO_(2)驱替及碳埋存机制,通过开展长岩心实验,对比分析气水不同组合驱替方式对提高采收率和CO_(2)埋存效果的影响。实验结果表明:水驱后CO_(2)与水交替驱采收率最高,其次为CO_(2)与水交替驱,而连续CO_(2)驱采收率最低,CO_(2)突破是影响采收率的关键因素,交替注入可以抑制气窜;油藏中CO_(2)埋存位置以大孔隙为主,气水交替驱比纯气驱更有利于小孔隙中CO_(2)埋存,埋存率从高到低依次为连续CO_(2)驱、CO_(2)与水交替驱、水驱后CO_(2)与水交替驱及水驱后CO_(2)驱。

海上低渗油田CO_(2)气水交替驱可行性实验研究

海上L油田属于特低渗透断块油藏,常规水驱开发难度大、注入压力高且储层能量亏空。为有效提高油田开发效果,以海上L油田特低渗透断块油藏为研究对象,开展靶区CO_(2)驱油机制、CO_(2)气水交替驱注入参数优化和CO_(2)气水交替驱效果评价研究,为目标油田CO_(2)驱可行性提供依据。结果表明,气水交替驱较水驱可提高采收率6.48%,CO_(2)气水交替驱最佳气液比为1∶1,最佳注气速度为1.0 mL/min,交替段塞大小为0.3 PV。该研究对海上L特低渗油田开发具有重要的指导意义。

低渗透油藏CO_(2)驱注采参数优化研究与应用——以胜利油田A区块为例

随着“双碳”政策的大力推行,围绕着碳捕集、碳利用和碳埋存的相关产业飞速发展,长远来看CO_(2)驱具有较广阔的应用前景。低渗透/超低渗透油藏储层具有复杂的孔隙空间结构,常规水驱开发均面临注水困难和采收率低的问题,而CO_(2)驱具有多种驱油机理,能较好地解决水驱开发困难的问题。针对胜利油田A区块的低孔低渗透油藏条件,基于原油组分信息和恒组成膨胀实验数据进行了PVT拟合并建立了具有7个拟组分的组分模型,得出初次混相压力为30.1 MPa,多次接触混相压力为26.6 MPa。首次提出了以气窜为限制条件的CO_(2)驱注气速度计算经验公式。基于均质组分模型针对A区块进行了CO_(2)驱油藏工程参数优化,确定了以五点法井网、井距为250 m、注气速度为20.0 t/d、生产压力为26.0 MPa的最佳注采参数;同时,以衰竭式开发、水驱、CO_(2)吞吐、连续注CO_(2)、气水交替(WAG)等不同开发方式进行了注采参数优化,将优化后不同开发方式的结果进行了对比分析,结果表明连续注气具有一定优势;最后,选取A区块的西南方向优势物性区作为开发试验区,进行了基于优化结果的1个井组的连续注气开发方案预测,结果表明井组10 a采出程度为15.1%,20 a采出程度为22.4%。

普通稠油吞吐后期转水驱可行性及现场应用

为改善处于热采吞吐后期普通稠油油藏的开发效果,提出了该类油藏吞吐后期转注水开发的新思路,并从原油流动性、吞吐后的地下温度场、压力场等方面分析了该开发方式的可行性机理。在孤岛油田进行了现场应用,显著改善了开发效果,提高了开发效益。对处于吞吐后期的普通稠油油藏具有一定的推广价值。

特低渗油藏CO_2非混相驱生产特征与气窜规律

基于吉林腰英台油田CO2非混相驱先导试验区生产动态数据、吸水(气)剖面监测、示踪剂监测、原油和地层水组成分析,研究CO2非混相驱油井生产特征和气窜规律。先导试验中较好地利用了CO2的萃取、降黏、膨胀原油体积、增大地层有效孔隙等特点,增油效果较明显。对于特低渗、强非均质性油藏,水驱或气驱过程均存在单层突进、平面指进现象,水气交替注入可有效提高波及体积,有助于缓解气窜,注水转注气后产油量增幅低于注气转注水,水气交替注入过程中注水半周期的调整对气驱开发效果改善起主要作用。腰英台油田油井见气类型包括沿裂缝方向见气、沿高渗条带见气和低渗区域见气。根据建立的油井气窜标准,保持油井见气但不气窜、减缓气油比上升速度是改善非混相驱效果的关键。关停气窜井、调整生产井井底流压、实施水气交替注入是控制气窜的良好措施。

低渗透油藏天然气驱提高采收率数值模拟研究

针对低渗透油藏的地质及开发特点,在PVT实验和相态拟合的基础上,应用数值模拟技术研究了天然气驱开发方式对开发效果的影响。研究结果表明,注天然气可以较大幅度的提高低渗透油藏的采收率;气水交替驱是最佳的开发方式,并且水驱后气水交替驱的效果比投产初期就采用气水交替驱效果更好。

低渗透油藏气水交替驱不同注入参数优化

气窜是影响低渗透油藏注气开发效果的重要因素,气水交替(WAG)注入方式可以很好地稳定驱替前缘,从而提高宏观波及效率。低渗透油藏渗流机理复杂,影响气水交替开发效果的参数多,为了得到最佳开发效果,有必要对注入方式和参数进行优化。文中利用数值模拟方法研究了CO2注入方式和注入参数等对低渗透油藏开发效果的影响,并对长庆油田某超低渗透油藏CO2水交替注入方式及参数进行了优化。结果表明,最佳注入方式为CO2水同步注入,注入周期为1 a,段塞气水比为1∶1,段塞最佳注入总量为0.44 HCPV,最佳注入层位为底部4个小层。

旱涝交替下控制灌溉对稻田节水及氮磷减排的影响

该文研究控制灌排技术对稻田水氮磷动态变化及节水减排效应的影响。于2015年5—10月在河海大学江宁校区节水园,在有底侧坑内进行水稻栽培试验,于水稻分蘖期、拔节孕穗期、抽穗开花期和乳熟期4个生育阶段进行控水试验,以常规控制灌溉为对照,测定稻田淹排水铵态氮(NH_4^+-N)、硝态氮(NO_3^--N)和总磷浓度变化。结果表明:旱转涝处理淹水初期稻田水中铵态氮(NH_4^+-N)、硝态氮(NO_3^--N)和总磷浓度显著高于涝转旱处理,这个时期地表和地下排水应该引起注意。控制灌排条件下灌水量减少7.4%~18.5%,排水量减少23.0%~43.5%,NH_4^+-N负荷减少18.5%~54.5%,NO_3^--N负荷减少16.8%~57.7%,总磷负荷减少34.2%~58.3%;其中拔节孕穗期和抽穗开花期在保证节水减排的同时,也能实现较高的产量;因此,控制灌排技术具有较好的节水减排效果,对南方稻作区灌排实践具有指导意义。