Optimization of Injection Parameters for Profile Control and Flooding in an Oilfield during High Water Cut Period

In order to improve the effect of water control and oil stabilization during high water cut period, a mathematical model of five point method well group was established with the high water cut well group of an Oilfield as the target area, the variation law of water cut and recovery factor of different injection parameters was analyzed, and the optimization research of injection parameters of polymer enhanced foam flooding was carried out. The results show that the higher the injection rate, the lower the water content curve, and the higher the oil recovery rate. As the foam defoamed when encountering oil, when the injection time was earlier than 80% of water cut, the later the injection time was, the better the oil displacement effect would be. When the injection time was later than 80% of water cut, the later the injection time was, the worse the oil displacement effect would be. The larger the injection volume, the lower the water content curve and the higher the recovery rate. After the injection volume exceeded 0.2 PV, the amplitude of changes in water content and recovery rate slowed down. The optimal injection parameters of profile control agent for high water content well group in Oilfield A were: injection rate of 15 m3/d, injection timing of 80% water content, and injection volume of 0.2 PV.

A Method for Calculating Oil Field Relative Permeability Curve by Using Water Drive Characteristic Curve in High Water Cut Stage

With the production of strong bottom water reservoir, it will soon enter the ultra-high water cut stage. After entering the ultra-high water cut period, the main means of stable production is liquid extraction. Large liquid volume has a certain impact on the physical property distribution and fluid seepage law of the oilfield. The relative permeability curve measured according to the industry standard is not used for the prediction of development indicators and the understanding of the dynamic law of the oilfield. In order to understand the characteristics of water drive law in high water cut stage of water drive oilfield, starting from the water drive characteristic curve in high water cut stage, the method for calculating the relative permeability curve is deduced. Through numerical simulation verification and fitting the actual production data, it is confirmed that the obtained relative permeability curve is in line with the reality of the oilfield, It can provide some guiding significance for understanding the production law and water drive law of strong bottom water reservoir in ultra-high water cut stage.

Experimental investigation on using CO_(2)/H_(2)O emulsion with high water cut in enhanced oil recovery

CO_(2) emulsions used for EOR have received a lot of interest because of its good performance on CO_(2)mobility reduction.However,most of them have been focusing on the high quality CO_(2) emulsion(high CO_(2) fraction),while CO_(2) emulsion with high water cut has been rarely researched.In this paper,we carried out a comprehensive experimental study of using high water cut CO_(2)/H_(2)O emulsion for enhancing oil recovery.Firstly,a nonionic surfactant,alkyl glycosides(APG),was selected to stabilize CO_(2)/H_(2)O emulsion,and the corresponding morphology and stability were evaluated with a transparent PVT cell.Subsequently,plugging capacity and apparent viscosity of CO_(2)/H_(2)O emulsion were measured systematically by a sand pack displacement apparatus connected with a 1.95-m long capillary tube.Furthermore,a high water cut(40 vol%) CO_(2)/H_(2)O emulsion was selected for flooding experiments in a long sand pack and a core sample,and the oil recovery,the rate of oil recovery,and the pressure gradients were analyzed.The results indicated that APG had a good performance on emulsifying and stabilizing CO_(2) emulsion.An inversion from H_(2)O/CO_(2) emulsion to CO_(2)/H_(2)O emulsion with the increase in water cut was confirmed.CO_(2)/H_(2)O emulsions with lower water cuts presented higher apparent viscosity,while the optimal plugging capacity of CO_(2)/H_(2)O emulsion occurred at a certain water cut.Eventually,the displacement using CO_(2)/H_(2)O emulsion provided 18.98% and 13.36% additional oil recovery than that using pure CO_(2) in long sand pack and core tests,respectively.This work may provide guidelines for EOR using CO_(2) emulsions with high water cut.

An effective method to predict oil recovery in high water cut stage

The water flooding characteristic curve method based on the traditional regression equation between the oil and water phase permeability ratio and the water saturation is inappropriate to predict the oil recovery in the high water cut stage. Hence, a new water flooding characteristic curve equation adapted to the high water cut stage is proposed to predict the oil recovery. The water drive phase permeability experiments show that the curve of the oil and water phase permeability ratio vs. the water saturation, in the semi-logarithmic coordinates, has a significantly lower bend after entering the high water cut stage, so the water flooding characteristic curve method based on the traditional regression equation between the oil and water phase permeability ratio and the water saturation is inappropriate to predict the oil recovery in the high water cut stage; therefore, a new water flooding characteristic curve equation based on a better relationship between ln（kro/k,.~） and S~ is urgently desirable to be established to effectively and reliably predict the oil recovery of a water drive reservoir adapted to a high water cut stage. In this paper, by carrying out the water drive phase permeability experiments, a new mathematical model between the oil and water phase permeability ratio and the water saturation is established, with the regression analysis method and an integration of the established model, the water flooding characteristic curve equation adapted to a high water cut stage is obtained. Using the new water flooding characteristic curve to predict the oil recovery of the GD3-block of the SL oilfield and the J09-block of the DG oil field in China, results with high predicted accuracy are obtained.

Layer regrouping for water-flooded commingled reservoirs at a high water-cut stage

Layer regrouping is to divide all the layers into several sets of production series according to the physical properties and recovery percent of layers at high water-cut stage, which is an important technique to improve oil recovery for high water-cut multilayered reservoirs. Dif- ferent regroup scenarios may lead to different production performances. Based on unstable oil-water flow theory, a multilayer commingled reservoir simulator is established by modifying the production split method. Taking into account the differences of layer properties, including per- meability, oil viscosity, and remaining oil saturation, the pseudo flow resistance contrast is proposed to serve as a characteristic index of layer regrouping for high water-cut multilayered reservoirs. The production indices of multi- layered reservoirs with different pseudo flow resistances are predicted with the established model in which the data are taken from the Shengtuo Oilfield. Simulation results show that the pseudo flow resistance contrast should be less than 4 when the layer regrouping is implemented. The K-means clustering method, which is based on the objec- tive function, is used to automatically carry out the layer regrouping process according to pseudo flow resistances. The research result is applied to the IV-VI sand groups of the second member of the Shahejie Formation in the Shengtuo Oilfield, a favorable development performance is obtained, and the oil recovery is enhanced by 6.08 %.

Application of New Water Flooding Characteristic Curve in the High Water-Cut Stage of an Oilfield

The oil production predicted by means of the conventional water-drive characteristic curve is typically affected by large deviations with respect to the actual value when the so-called high water-cut stage is entered.In order to solve this problem,a new characteristic relationship between the relative permeability ratio and the average water saturation is proposed.By comparing the outcomes of different matching methods,it is verified that it can well reflect the variation characteristics of the relative permeability ratio curve.Combining the new formula with a reservoir engineering method,two new formulas are derived for the water flooding characteristic curve in the high water-cut stage.Their practicability is verified by using the production data of Mawangmiao and Xijiakou blocks.The results show that the error between the predicted cumulative oil production and production data of the two new water drive characteristic curves is less than the error between the B-type water drive characteristic curve and the other two water drive characteristic curves.It is concluded that the two new characteristic curves can be used to estimate more accurately the recoverable reserves,the final recovery and to estimate the effects of water flooding.

Wall Sticking of High Water-Cut, Highly Viscous and High Gel-Point Crude Oil Transported at Low Temperatures

Some crude oils with high water cut have the capability to flow below the oil gel point, while the oil particles adhere to the pipe wall in the form of paste, also called "wall sticking". Wall sticking is a serious problem during the pipeline transportation, leading to partial or total blockage of the pipeline and energy wastage. In this paper, a series of laboratory flow loop experiments were conducted to observe the wall sticking characteristics of crude oil with high water cut, high viscosity and high gel point at low transportation temperatures. The effects of shear stress and water cut on the wall sticking rate and occurrence temperature were investigated. Experimental results indicated that the wall sticking rate and occurrence temperature were lower under stronger shear stress and higher water cut conditions. A criterion of wall sticking occurrence temperature(WSOT) and a regression model of wall sticking rate were then established. Finally, the software was developed to calculate the pressure drop along the pipelines of crude oils with high water-cut. It was able to predict the wall sticking thickness of gelled oil and then calculate the pressure drop along the pipelines. A typical case study indicated that the prediction results obtained from the software were in agreement with actual measured values.

高含水油井关停后剩余油再富集速度研究

高含水断块油藏开发末期构造高部位油井在关井一段时间后,会产生剩余油再富集现象。目前关于剩余油再富集速度的研究中,对剩余油运移过程的影响因素考虑不够全面,影响计算精度。针对该问题,在对运移中剩余油再富集受力分析的基础上建立小油滴状和柱状剩余油再富集速度模型,通过正交试验确立2种剩余油再富集速度的主要敏感因素,并建立了2种剩余油再富集速度及再富集时间图版。研究结果表明:存在驱替压差时,储层渗透率为影响2种剩余油再富集速度的主控因素;当储层渗透率一定,驱替压差的增大和原油黏度的减小有利于2种剩余油再富集速度的增大;同一注采井距位置处的小油滴距离孔隙中滞留柱状剩余油越近,聚集过程中剩余油再富集时间越长,但数值上增加不多。该研究对高含水油藏剩余油再富集潜力区评价具有借鉴意义。

基于投影寻踪模型的特高含水油藏剩余油可采潜力评价方法

影响特高含水油藏剩余油可采潜力的因素极其复杂,且各因素的影响程度差异明显,常规方法多以剩余油饱和度或剩余油储量丰度等单一指标评价剩余油潜力,难以有效指导特高含水油藏剩余油挖潜。在充分考虑特高含水油藏剩余油可采潜力影响因素的基础上,综合表征储层非均质性、剩余油可采储量规模、水淹状况以及油水分流能力的差异,构建了特高含水油藏剩余油可采潜力量化评价指标体系,并考虑不同指标对剩余油可采潜力控制程度的差异,将加速遗传算法与投影寻踪模型相结合来确定各评价指标的客观权重,从而构建了剩余油可采潜力指数,形成特高含水油藏剩余油可采潜力量化评价新方法。以渤海Q油田南区主力产层NmIL砂体为例,开展特高含水油藏剩余油可采潜力量化评价,结果表明,新方法可综合表征不同区域位置的储层物性、可采储量丰度和油水分流能力对剩余油可采潜力的影响,实现了主力产层NmIL砂体剩余油可采潜力分布的差异化定量评价,优势可采潜力区域刻画明显,将其作为NmIL砂体下一步井网加密调整潜力区域,以精准指导加密水平井的部署,为特高含水油藏剩余油挖潜提供了一种全新的分析方法与思路。

高含水老油田化学驱综合治理新方法及工程实践路径

针对胜利高含水老油田化学驱在科学、技术、管理、工程四个角度面临的开发矛盾,以渤76块为典型单元,在工程实践中进行具体对策分析,构建了“适、专、快、集”的老油田化学驱综合治理新方法。“适”指在老油田科学开发方式转化上,构建不同油藏类型老油田化学驱最佳介入时机模型,提出了在含水率相对较低的阶段,是适合化学驱的有利时机,高效开发方式需“适”介入。“专”指在老油田开发技术应用上,改变传统聚合物先溶解后注入的开发思路,研制可控相转化聚合物,使聚合物先注入后溶解,解决炮眼剪切降解的难题,提高油水流度控制能力,老油田开发矛盾需“专”治理。“快”指在老油田综合管理模式上,改变传统方式,即矿场提问题、研究院设计方案、化工厂生产驱油剂的“串联”管理模式,提出充分发挥矿场、研究院、生产厂三方优势的“并联”管理模式,形成针对单一油藏的产品工业化工艺包以及产业化落地方案,老油田开发技术实现“快”转化。“集”指在老油田工程应用实践上,打破老油田化学驱地面大规模建站的工程工艺模式,采用集约化撬装配注设备,实现老油田化学驱的集约快速配注,老油田工程工艺实现“集”应用。运用上述方法,在胜利油田渤76块综合含水率上升初期,实施由水驱转为可控相转化聚合物驱,实施后一年即见到明显的降水增油效果,单井日产油水平增加8.6t/d,综合含水率降低3.1%,验证了综合治理模式的可行性,为高含水老油田化学驱高效开发提供了有效路径。

断块油藏高含水井关井后剩余油再动用运移规律微观模拟

基于微观可视化光刻玻璃模型,从微观角度定性、定量研究了断块油藏高含水井关井后剩余油再动用运移规律,并开展了影响因素分析。结果表明:水驱后关井期间剩余油再动用类型主要为滴状、柱状和簇状。关井期间剩余油会沿模型倾斜方向向高部位运移聚集,有利于后续水驱阶段进一步提高驱油效率。地层倾角的增大、原油黏度的减小有利于剩余油再动用;关井时间的增加有利于剩余油向高部位采出端接近聚集;后续水驱阶段注入速度的增大会增加波及面积。

缓交联高强度封堵剂研究进展

综述了目前油田主要应用的封堵剂的发展情况,介绍了含水率较高的油田实施窜流封堵技术,分析了不同类型的深部封堵剂优劣特性及适用情况,总结和展望了未来缓慢交联的封堵剂技术的发展趋势。

极端耗水层带形成机制及流场调控增效模式——以陆相砂岩特高含水后期整装油田为例

以胜利油区陆相砂岩油藏整装油田为代表,主力单元进入特高含水后期(含水率大于95%),局部区域出现极端耗水现象,水油比急剧上升,注入水利用率大幅下降,吨油操作成本成倍增加,经济效益变差,但油藏中还有60%左右剩余地质储量。注入水沿着极端耗水层带窜流是制约陆相砂岩整装油田特高含水后期效益开发的关键问题。以提高特高含水老油田开发效益为目标,明晰了极端耗水层带形成机制及调控机理,建立了基于老井的变流线调控极端耗水层带扩波及方法,形成特高含水后期油藏精准描述及调控极端耗水层带扩波及的效益开发技术体系。通过应用流场调控技术,使传统认为含水率98%近废弃油藏开展示范应用,基于极端耗水层带流场调控经济寿命期延长10a以上,产油量大幅增加,含水率下降,吨油操作成本下降,实现了特高含水后期老油田低成本开发。

江苏油田复杂小断块高含水油藏注采井网优化技术

江苏油田复杂小断块油藏经过长期的注水开发后,目前处于中高含水开发期。现阶段储层非均质性对注采井网的影响更加突出,局部存在低效无效注水循环问题,亟需优化调整注采井网。根据非均质油藏剩余油富集类型和影响因素,在原井网基础上,利用油藏数值模拟方法,开展相控条件下的注采井网优化技术政策研究。根据模拟结果,确立了抽稀井网和转注高含水油井两种注采井网优化技术的政策界限,指导陈2断块、韦2断块注采井网优化调整,取得了良好的应用效果,为改善高含水油藏水驱开发效果提供了技术支撑。

高强度堵剂优化及其在高含水油藏靶向调堵中的应用

针对河南油田高渗高凝特高含水砂岩油藏,对双激发无机堵剂的配方优化、耐温耐盐性能、封堵性能、耐冲刷性能、粒径匹配等多方面进行系统研究。结果表明,缓凝剂和离子平衡剂是控制体系凝固时间的主导因素,随着主剂与激发剂浓度以及温度的增加,双激发无机堵剂固结速度增大。配液水中矿化度较高时,硫酸根和氯盐会加快体系固结时间。双激发无机堵剂封堵能力强,耐冲刷能力和深部液流转向效果较好,可对高渗透层大孔道有效封堵,提高低渗岩芯分流率,其封堵率高于98.5%。现场应用效果证实,双激发无机堵剂能够实现深部靶向封堵,具有强度高、有效期长、成本低等优点,调堵后含水率大幅下降。

高含水油田剩余油研究方法、分布特征与发展趋势

为了提高高含水油田剩余油研究与评价效果,基于大量文献调研,梳理了剩余油的概念、影响因素,从剩余油微观分布、宏观分布和饱和度定量分析3个方面总结了剩余油研究方法及其适用条件,概括了水驱油藏、稠油油藏和化学驱油藏的剩余油分布特征,进一步提出了目前剩余油研究的难点和发展趋势。结果表明:剩余油的影响因素主要包括地质构造、沉积微相、储层非均质性和井网密度、井网模式、注采系统的完善程度、生产动态等;剩余油研究方法包括实验分析方法、数值模拟方法和矿场测试方法等,各种方法的研究目的和适用条件不同,测试结果反映不同位置、不同尺度下的剩余油饱和度分布;高含水油田剩余油分布总体呈现高度分散和相对富集的特征,剩余油微观分布呈现连续相和非连续相多种形式;剩余油研究发展趋势包括但不限于以下5方面:超大物理模型的构建、多尺度高分辨率成像系统集成、考虑不同驱替介质及物性时变与非连续相非线性渗流的数值模拟改进方法、多学科多方法矿场测试的综合应用及大数据人工智能的广泛应用。

海上高含水油井分段开采的选井方法应用研究

海上边底水油藏一旦见水会迅速进入高含水阶段,而分段开采可以达到抑制高含水和延长油井寿命的目的。因此,可利用分段开采机理模型对含水上升影响因素进行敏感性分析,研究高含水油井分段开采的选井方法依据,并利用数值模拟方法进行验证。结果表明:1)底水油藏水平井含水上升影响因素敏感性大小排序为黏度>高低渗级差>高渗条带比例>最大产液>高渗段渗透率。2)根据生产动态、水平段地质资料及邻井资料将海上底水油藏高含水水平井见水模式分为线性见水全面水淹、点状见水局部水淹和多点见水全面水淹,其中点状见水局部水淹模式可进行分段开采。以典型井A1为例,利用所建选井方法流程判断含水率曲线为线状见水特征,开井含水高,水平段渗透率分段特征明显,Ⅲ-1小层水淹程度较高,A1井跟部水淹严重,且由于第1套夹层遮挡,A1井趾部水淹程度较低,为点状见水模式局部水淹,符合分段开采特征。3)针对点状见水局部水淹水平井,采用分段开采进行稳油控水,利用数值模拟方法模拟预测,分段开采方案开发较不分段方案产油量和采收率得到显著提升,验证了选井方法及分段开采的适用性。提出的选井方法流程可为现场水平井分段开采选井研究提供方法依据。

海上油田“双高”阶段低效井综合治理研究

X油田是渤海典型的化学驱结束后续水驱油田,目前处于高含水及高采出程度的“双高”阶段,为解决开发生产过程中低产低效井逐渐增多且治理难度逐渐增加的问题,对油田储层沉积微相、地层物性参数、剩余油挖潜历程、开发方式转变、注采井网调整、增产措施影响等因素开展研究,分析低效井成因主要包括储层条件导致含水突升、井网不完善导致能量下降、过筛管压裂后采油井出砂等。针对不同成因低效井开展了分类治理研究,提出了区域流场调整、分层系开发、防砂筛管补贴等治理措施。20202021年矿场实践表明,对X油田12口低效井实施针对性的治理措施,单井平均高峰日增油达18 m^(3),预测治理有效期内将累增油21×10^(4)m^(3),该油田的低效井治理技术使油藏生产能力得到有效释放,为同类海上油田低效井治理提供了参考和借鉴。

杏北开发区葡Ⅰ1~3聚驱注入界限实验研究

特高含水期油田注聚合物能够有效封堵大孔道,改变液流方向,提高波及体积,从而提高采收率。针对杏北开发区葡Ⅰ1~3主力非均性储层聚驱注入界限识别不清、注入参数选取缺乏依据的问题,基于不同储层渗透率、聚合物相对分子质量和聚合物质量浓度开展注入性实验,评价了注聚效果,确定了注聚界限。结果表明:聚合物相对分子质量越大、质量浓度越大,注入速度越低;注入速度高于0.35 m·d^(-1)为注入能力强,0.35~0.25 m·d^(-1)为注入能力中等,0.25~0.15 m·d^(-1)为注入能力较差,小于0.15 m·d^(-1)为注入能力差。

高含水区域膨胀土边坡失稳特性与处理技术研究

高含水区域的膨胀土边坡是一种常见的地质灾害形式,其失稳性对于工程建设和地质环境具有重要影响。该研究旨在探究高含水区域膨胀土边坡的失稳特性,并提出相应的处理技术。通过实际工程调查,分析高含水区域膨胀土边坡的失稳特性和力学性能。结合现有的加固处理技术,提出适用于高含水区域膨胀土边坡的处理方法,包括土体排水降湿、边坡加固结构的设计和施工等内容。研究表明,高含水条件下膨胀土的含水量增加会导致其体积膨胀和强度降低,从而增加边坡失稳风险。采用排水降湿法可以有效降低高含水区域膨胀土边坡的失稳风险,保障工程建设的安全和可持续发展。