Dissipative particle dynamics simulation of wettability alternation phenomena in the chemical flooding process

Wettability alternation phenomena is considered one of the most important enhanced oil recovery （EOR） mechanisms in the chemical flooding process and induced by the adsorption of surfactant on the rock surface. These phenomena are studied by a mesoscopic method named as dissipative particle dynamics （DPD）. Both the alteration phenomena of water-wet to oil-wet and that of oil-wet to water-wet are simulated based on reasonable definition of interaction parameters between beads. The wetting hysteresis phenomenon and the process of oil-drops detachment from rock surfaces with different wettability are simulated by adding long-range external forces on the fluid particles. The simulation results show that, the oil drop is liable to spread on the oil-wetting surface and move in the form of liquid film flow, whereas it is likely to move as a whole on the waterwetting surface. There are the same phenomena occuring in wettability-alternated cases. The results also show that DPD method provides a feasible approach to the problems of seepage flow with physicochemical phenomena and can be used to study the mechanism of EOR of chemical flooding.

Theory and Application of Numerical Simulation of Chemical Flooding in High Temperature and High Salt Reservoirs

Applications, theoretical analysis and numerical methods are introduced for the simulation of mechanical models and principles of the porous flow in high temperature, high salt, complicated geology and large-scale reservoirs in this paper. Considering petroleum geology, geochemistry, computational permeation fluid mechanics and computer technology, we state the models of permeation fluid mechanics and put forward a sequence of implicit upwind difference iteration schemes based on refined fractional steps of the upstream, which can compute the pressures, the saturation and the concentrations of different chemistry components. A type of software applicable in major industries has been completed and carried out in numerical analysis and simulations of oil extraction in Shengli Oil-field, which brings huge economic benefits and social benefits. This software gives many characters: spatial steps are taken as ten meters, the number of nodes is up to hundreds of thousands and simulation time period can be tens of years and the high-order accuracy can be promised in numerical data. Precise analysis is present for simplified models of this type and that provides a tool to solve the international famous problem.

Micro-mechanisms of residual oil mobilization by viscoelastic fluids

Four typical types of residual oil, residual oil trapped in dead ends, oil ganglia in pore throats, oil at pore corners and oil film adhered to pore walls, were studied. According to main pore structure characteristics and the fundamental morphological features of residual oil, four displacement models for residual oil were proposed, in which pore-scale flow behavior of viscoelastic fluid was analyzed by a numerical method and micro-mechanisms for mobilization of residual oil were discussed. Calculated results indicate that the viscoelastic effect enhances micro displacement efficiency and increases swept volume. For residual oil trapped in dead ends, the flow field of viscoelastic fluid is developed in dead ends more deeply, resulting in more contact with oil by the displacing fluid, and consequently increasing swept volume. In addition, intense viscoelastic vortex has great stress, under which residual oil becomes small oil ganglia, and finally be carried into main channels. For residual oil at pore throats, its displacement mechanisms are similar to the oil trapped in dead ends. Vortices are developed in the depths of the throats and oil ganglia become smaller. Besides, viscoelastic fluid causes higher pressure drop on oil ganglia, as a driving force, which can overcome capillary force, consequently, flow direction can be changed and the displacing fluid enter smaller throats. For oil at pore corners, viscoelastic fluid can enhance displacement efficiency as a result of greater velocity and stress near the corners. For residual oil adhered to pore wall, viscoelastic fluid can provide a greater displacing force on the interface between viscoelastic fluid and oil, thus, making it easier to exceed the minimum interfacial tension for mobilizing the oil film.

The mechanism of hydraulic fracturing assisted oil displacement to enhance oil recovery in low and medium permeability reservoirs

Aiming at the technology of hydraulic fracturing assisted oil displacement which combines hydraulic fracturing,seepage and oil displacement,an experimental system of energy storage and flowback in fracturing assisted oil displacement process has been developed and used to simulate the mechanism of percolation,energy storage,oil displacement and flowback of chemical agents in the whole process.The research shows that in hydraulic fracturing assisted oil displacement,the chemical agent could be directly pushed to the deeper area of the low and medium permeability reservoirs,avoiding the viscosity loss and adhesion retention of chemical agents near the pay zone;in addition,this technology could effectively enlarge the swept volume,improve the oil displacement efficiency,replenish formation energy,gather and exploit the scattered residual oil.For the reservoir with higher permeability,this measure takes effect fast,so to lower cost,and the high pressure hydraulic fracturing assisted oil displacement could be adopted directly.For the reservoir with lower permeability which is difficult to absorb water,hydraulic fracturing assisted oil displacement with surfactant should be adopted to reduce flow resistance of the reservoir and improve the water absorption capacity and development effect of the reservoir.The degree of formation energy deficit was the main factor affecting the effective swept range of chemical agents.Moreover,the larger the formation energy deficit was,the further the seepage distance of chemical agents was,accordingly,the larger the effective swept volume was,and the greater the increase of oil recovery was.Formation energy enhancement was the most important contribution to enhanced oil recovery(EOR),which was the key to EOR by the technology of hydraulic fracturing assisted oil displacement.

大庆油田萨中化学驱注入井附近地带油层堵塞机理及解堵剂配方优化

化学驱的规模应用,不断刷新着大庆油田采收率极限,成为油田持续有效开发的重要技术,但随着化学驱注剂量增加,地层近井地带堵塞严重,部分井欠注现象日益突出,影响区块开发效果。针对洗井吐液中大量的胶团导致近井地带堵塞的问题,利用仪器检测和物理化学分析等手段对化学驱返吐的堵塞物进行分析,明确堵塞物成分并揭示堵塞机理。结果表明:聚合物胶团主要成分是有机物,夹杂金属离子和垢质,呈高黏无弹性、胶联状排列的致密结构;Fe^(3+)和Al^(3+)是导致聚合物形成胶团的主要原因,污水中的细菌发生氧化还原反应腐蚀管线产生Fe^(3+),生成胶团临界质量浓度为1.5 mg/L;碱溶蚀地层产生Al^(3+),生成胶团临界质量浓度为1.375 mg/L;针对堵塞物成分开展解堵剂优化研究,形成了采油1-1型和采油1-2型2种解堵剂,现场实施10口井,平均单井注入压力下降了1.4 MPa,平均单井日增注量为23 m^(3),累计增注量为973 m^(3)。研究成果可有效指导化学驱欠注井治理,对化学驱提质增效具有重要意义。

无碱表面活性剂-聚合物复合驱技术研究进展

无碱表面活性剂-聚合物二元复合驱可避免碱引起的结垢、乳化、腐蚀等负面作用,降低投资和操作成本,是具有应用前景的化学驱提高石油采收率新技术。目前存在主要问题有:缺少高效稳定的活性剂工业化产品,驱油机理及主要影响因素理论研究薄弱,评价方法不健全,矿场试验少、技术风险较大。影响表面活性剂-聚合物二元复合驱驱油效率的主要因素有体系黏度、界面张力、乳化强度等,二元体系具有较高的黏度是提高采收率的重要保障,体系油水界面张力越低驱油效率越高,体系乳化性能也显著影响驱油效果。表面活性剂-聚合物二元复合驱矿场试验取得了一定效果,但也暴露出一些问题,需要提高配方适应性、驱油剂产品质量稳定性,优化注入方案,加强现场监测和跟踪调整等。

化学复合驱技术研究与应用现状及发展趋势

近年来化学复合驱技术应用基础研究及现场试验得到了长足发展。国内采用低浓度复合驱体系,通过碱、表面活性剂的协同作用,降低油水界面张力达到超低数量级,同时采用抗盐聚合物使污水配制驱替液黏度达到要求,三元复合驱或二元复合驱具有提高驱油效率和扩大波及体积双重作用。大庆油田三元复合驱先导性试验和工业化试验提高采收率幅度达到18.6%～26.5%,复合驱进入工业化推广应用阶段,在复合驱试验过程中逐步形成了系列配套技术。复合驱存在的主要问题为强碱引起的检泵周期较短和采出液处理难度大、成本高。国外复合驱技术早期主要采用表面活性剂胶束-聚合物驱,由于成本高未能推广应用,近年来随着油价上涨,开始研究低浓度复合驱体系。国外采用化学驱的油藏大部分为高温高盐油藏,瓶颈技术为耐温抗盐驱油剂的研制。

稠油化学降粘复合驱提高采收率实验研究

受地层压力高、储层厚度薄、边底水活跃等油藏条件影响,部分稠油油藏热采时的热损失大、成本高、采收率低,难以得到有效开发。通过室内驱油实验,研究稠油降粘剂驱、聚合物驱以及化学降粘复合驱提高采收率机理,对比分析不同驱油体系对于稠油提高采收率效果的影响。实验结果表明:利用水溶性降粘剂和聚合物组成稠油化学降粘复合驱驱油体系,可以提高采收率16.04%,优于仅使用降粘剂或聚合物作为驱油剂。对于稠油化学降粘复合驱效果,从换油效率角度考虑,优化复合驱段塞中聚合物和水溶性降粘剂的质量分数分别为0.3%和1.0%;从提高采收率角度对比,优化采用前置聚合物段塞后置水溶性降粘剂段塞的注入方式,相比于前置水溶性降粘剂段塞后置聚合物段塞的注入方式,可提高采收率7.2%~10.7%;在此基础上,优化得到水溶性降粘剂与聚合物段塞的最佳体积比为3∶2。在非均质模型和微观可视化模型中,化学降粘复合驱不仅兼具聚合物和降粘剂的驱油机理,而且还产生了协同增效作用,对于稠油较单一化学剂驱可大幅度提高波及范围和洗油效率。

化学驱数值模拟技术

随着化学驱技术在油田矿场的推广应用,现有软件的化学驱模拟功能越来越难以满足油田实际需求.通过调研化学驱数值模拟技术,阐述油藏数值模拟技术的发展现状,并将CMG、ECLIPSE、UTCHEM等8种软件分为综合型软件化学驱模块和单一化学驱软件两类,分析各软件的优缺点,对比各软件的综合性能及化学驱功能,指出化学驱数值模拟软件技术存在的主要问题及发展方向.现有软件在增强前后处理功能的同时,还需进行核心的完善.化学驱软件考虑众多物理化学因素,导致求解困难,需要在数值模拟的稳定性和机理描述的合理性之间进行适当取舍.虽然国产数值模拟软件在整体性能上弱于国外商业化软件,但是在化学驱数学模型和机理描述上具备较大优势.

天然岩芯化学驱采收率机理的一些认识

用牛顿流体驱替一定的均质多孔介质系统结果显示,驱油效率由驱替液的毛管数决定。用化学液驱替天然岩芯时,除毛管数以外,还有很多其他因素影响驱油效率。天然岩芯,即使在宏观上是均匀的,在微观上也不均匀;驱替时所得到的效率一般被称为驱油效率,实质上是微观波及效率和驱油效率的乘积。牛顿流体没有弹性,驱替时,体系的润湿性不发生变化,不出现渗吸作用,不形成乳液,孔隙的几何形状不发生变化。但是,用化学液驱替天然岩芯时,由于化学液为粘弹性,体系有润湿性的改变,会出现乳化现象,渗吸作用也会出现。上述因素都会影响驱油效率,尤其是当多种因素同时作用时。分析了极限采收率和经济采收率的区别。很多文章都论述极限采收率,但经济采收率对油田的作用更大。化学驱应考虑上述因素,这对设计、开发、筛选化学剂以及确定驱油体系会是有益的,将深化我们对化学驱机理的认识,促进这方面更深入的研究。

聚合物/羧基甜菜碱二元复合体系驱替水驱后残余油的机理

实验研究在30℃下进行。实验聚表二元复合体系为1.0 g/L HPAM、2.0 g/L羧基甜菜碱在矿化度3.7 g/L的模拟大庆油田采出水中的溶液,与模拟大庆油(黏度10 mPa.s)间的界面张力为5.8×10-3mN/m,1-1000 s-1范围的表观黏度与1.0 g/L HPAM溶液十分接近。在玻璃刻蚀大庆油藏仿真均质微观模型上,水驱20 PV的采收率为55.795%,注入20 PV二元体系使采收率增加39.724%;在二元复合体系驱替过程中,注入、采出口之间主流区域内的水驱后残余油在二元复合体系作用下发生变形,伸长并形成油丝,主要以油丝的形式被驱出;过渡区和边角区的残余油则主要以W/O乳状液的形式被驱出。W/O乳状液中的乳化水滴通过圈闭、Y型孔道挤压及水滴变形、断裂这3种方式形成并汇集为比较连续的W/O乳状液流,二元复合体系以W/O乳状液的形式由主流区扩展到两侧的过渡区,再进入边角区,启动死油区的残余油,从而扩大了波及体积,提高了驱油效率。图5参11。

化学驱提高原油采收率的研究进展

注化学剂驱油是我国油田现用提高采收率的主要技术手段,本文以影响原油采收率的主要因素为切入点,综述了表面活性剂、聚合物、三元/二元复合驱等常规三次采油技术的应用研究进展,重点总结了以功能性纳米材料为主剂的纳米驱油技术最新研究成果,阐述了其在提高原油采收率中的作用机制.最后,针对基于功能性纳米材料的驱油技术,探讨了该研究领域亟待解决的问题和面临的挑战,并对该领域的发展趋势给予了展望.

淹水土壤中镉活性变化及其制约机理

近年来,面对全球土壤Cd污染日益严重的现状,国内外许多专家和学者对土壤中Cd的迁移转化进行了大量的探索和研究。但是,由于土壤自身的复杂性以及影响因素的多样性和不确定性,有关淹水土壤中镉(Cd)活性变化及其制约机理的研究常常出现截然不同甚至相反的报道。铁锰氧化物、碳酸盐、固相有机质、硫化物、DOM、阴离子(主要是Cl-和SO42-)和阳离子(如Al3+、Ca2+、Mg2+、Na+等)等繁多的制约因素及其制约机理使得Cd的土壤化学理论复杂化,也给土壤Cd污染的控制和治理带来困难。本文从Cd在土-水界面发生迁移转化的化学过程(吸附与解吸、沉淀与溶解和配位与螯合)入手,总结并阐述了淹水土壤中Cd活性的变化及其制约机理,同时对该领域的研究进行了展望,试图为淹水土壤中Cd活性的深入研究和Cd污染土壤的修复与治理提供参考。

中低渗透储集层压驱提高采收率机理

针对压裂、渗流、驱油相结合的压驱技术研究需求,研发了压驱储能及反向压驱回注实验系统,模拟了压驱过程中压驱剂的渗流-储能-洗油-返排作用机理。研究表明:压驱技术将压驱剂直接输送至中低渗透储集层深部,可有效避免压驱剂在近井地带的黏度损失与黏附滞留,具有扩大波及体积、提高洗油效率、补充地层能量并将零散分布的剩余油汇集采出的效果。渗透率较高的储集层,压驱见效快,为降低成本,可直接采用高压注水压驱。渗透率较低的储集层吸水困难,采用表面活性剂压驱可有效降低储集层渗流阻力,提高储集层吸水能力与开发效果。地层能量亏空程度是影响压驱剂有效波及范围的主要因素,地层能量亏空越大,化学剂渗流距离越远,有效波及体积越大,采收率提高幅度越大;地层增能作用对提高采收率的贡献最大,是压驱技术提高采收率的关键。

化学驱互溶驱替组分输运机理研究

建立了化学驱互溶驱替组分输运数学模型，将模型中所需的物化参数描述为驱油剂浓度相关的函数。定义了“有效 驱替带长度”参数，来量化和分析吸附、扩散弥散、段塞尺寸和驱替速度等多因素对组分输运过程与结果的影响机理。分析 了大庆油田ＡＳＰ复合驱常用驱油剂（表面活性剂ＯＲＳ－４１和碱ＮａＯＨ）在孔隙输运过程中的有效性和持久性。研究成果不 仅可以为复合驱工程工艺方案设计和动态监测提供指导，而且可用于代替部分实验室流动实验和辅助机理研究。研制的 模拟软件的显著特点是对注化学剂段塞情况下的数学模型计算进行了十分巧妙的边界条件处理，用有限差分的预测－校正 格式使计算结果更为准确可靠，其可靠性可用相应的物理模拟（流动）实验进行验证。

聚合物驱相对渗透率曲线的特征研究

本文在研究聚合物溶液流经多孔介质时的流变性基础上，确定了聚合物溶液在多孔介质的有效粘度与分流量和相饱和度之间的关系式。从而解决了聚合物吸附／滞留及非牛顿流效应的影响，建立了稳定法测定聚合物驱相对渗透率曲线的实验技术和方法。成功地测得了油／聚合物溶液体系的相渗曲线和注聚合物段塞后的油／水体系的相渗曲线，并确定了适当的相渗曲线经验方程。讨论了聚合物驱相渗曲线的特征，分析了水相中的自由聚合物分子和岩石中吸附／滞留的聚合物对相渗曲线的影响，真实地反映了聚合物驱过程中的多相渗流规律。

化学驱油体系中各组分在油砂表面上静吸附特征研究

针对辽河油田某区块原油筛选优化出的化学驱油体系配方,开展了组成体系中的阴离子型表面活性剂、非离子型表面活性剂、聚合物及碱剂,在辽河油田特定区块油砂上的静吸附特征和吸附损失量的研究。通过实验得出了驱油剂在不同体系组成中的静吸附规律不同,吸附量大小不同。多组分的复合驱油体系中单剂的静吸附量小;碱剂在含有聚合物的体系中静吸附量较大;由聚合物、碱、非离子型表活剂和阴离子型表活剂组成的四组分ASP三元驱油体系中各单剂的静态吸附损失量最小,阴离子型表活剂的存在,减少非离子表活剂在岩石表面上的吸附损失量。不同化学驱油体系中单剂的静吸附损失的研究结果,对矿场实施化学驱油试验体系配方的确定、组成及段塞的设计和油藏数值模拟等提供科学依据和基础实验数据,具有一定的现实意义和指导意义。

河口油田普通稠油油藏化学驱技术研究

以河口油田普通稠油油藏油样为实验对象,通过微观驱替实验研究碱驱提高稠油采收率的机理,通过填砂管驱替实验观察碱驱、碱/聚合物驱和碱/表面活性剂驱3种体系的驱油效果。研究发现:碱驱波及系数高于水驱波及系数;碱质量分数越高,波及系数越大,采收率也越好;碱渗入原油中产生泡状流,是导致碱驱波及系数高的主要原因。聚合物和碱进行复配后,虽然黏度较高,但抑制了碱液向原油中的渗入。表面活性剂的引入也会对泡状流的形成产生负面影响,导致碱/表面活性剂驱的波及系数较低。

二元复合体系微观驱油机理可视化实验

针对胜利油区油藏条件,运用新型表面活性剂—聚合物二元复合体系,对其开展了微观模型(岩心薄片)驱油和常规柱状岩心可视化驱油实验。以水驱效果为基础,对比了表面活性剂、聚合物、二元复合体系的驱油效果,重点研究了微观孔隙中表面活性剂、聚合物以及二元复合体系的洗油和携油性能及其在驱油过程中的微观渗流特征,深入分析了二元复合体系的微观驱油机理。结果表明:与聚合物和表面活性剂相比,二元复合体系的驱油效果更好。在岩心薄片可视化驱油实验中,由于3种不同的驱替溶剂波及效率不同,最终导致驱替结束后岩心薄片中剩余油的面积有所不同,采用二元复合体系驱替后,剩余油的面积最小,表明其驱油效率最高,比聚合物和表面活性剂的驱油效率分别提高了2.59%和11.80%;对于常规柱状岩心,二元复合体系比聚合物和表面活性剂的驱油效率分别提高了1.43%和20.70%。

化学蒸汽驱提高驱油效率机理研究

化学蒸汽驱的目的是解决胜利油区中深层稠油油藏因油层压力高导致蒸汽驱采收率低的技术瓶颈。采用室内物理模拟实验,以数值模拟技术为手段,通过研究高温泡沫剂一高温驱油剂一原油组分的相互作用机制及温度、油水界面张力对驱油效率的影响,对比高温泡沫剂辅助蒸汽驱、高温驱油剂辅助蒸汽驱、高温泡沫剂与高温驱油剂辅助蒸汽驱提高采收率的幅度,揭示了化学剂与蒸汽复合作用提高采收率机理。结果表明,高温驱油剂的油水界面张力达到10^(-3)mN/m数量级,才能取得较好的驱油效果,可提高驱油效率5.1%;高温泡沫剂的临界含油饱和度为0.25～0.3,可提高驱油效率8.1%;与蒸汽驱相比,化学蒸汽驱可发挥高温驱油剂和泡沫剂的协同作用,提高驱油效率14.6%,具有明显的技术优势。