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.

A laboratory study of hot WAG injection into fractured and conventional sand packs

Gas injection is the second largest enhanced oil recovery process,next only to the thermal method used in heavy oil fields.To increase the extent of the reservoir contacted by the injected gas,the gas is generally injected intermittently with water.This mode of injection is called water-alternating-gas(WAG).This study deals with a new immiscible water alternating gas(IWAG) EOR technique,"hot IWAG" which includes combination of thermal,solvent and sweep techniques.In the proposed method CO2 will be superheated above the reservoir temperature and instead of normal temperature water,hot water will be used.Hot CO2 and hot water will be alternatively injected into the sand packs.A laboratory test was conducted on the fractured and conventional sand packs.Slugs of water and CO2 with a low and constant rate were injected into the sand packs alternatively;slug size was 0.05 PV.Recovery from each sand pack was monitored and after that hot water and hot CO2 were injected alternatively under the same conditions and increased oil recovery from each sand pack and breakthrough were measured.Experimental results showed that the injection of hot WAG could significantly recover residual oil after WAG injection in conventional and fractured sand packs.

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。

江苏油田CO_2混相驱现场试验研究

对江苏油田富 14断块进行的可行性研究结果表明 ,复杂小断块油藏可以进行经济有效的CO2 混相驱。江苏油田富 14断块在保持最低混相压力的状态下 ,于 1998年末开始进行了CO2 —水交替 (WAG)的注入试验。进行了 6周期的注入试验后 ,水气比由 0 86∶1升至 2∶1。油井见到了明显的增油降水效果 ,水驱后油层中形成了新的含油富集带。试验区采油速度由 0 5 %升至 1 2 % ,综合含水率由 93 5 %降至 6 3 4%。到目前为止 ,CO2 波及区采收率已提高 4% ,CO2 利用率为 12 40m3/t(油 )。试验仍在继续进行。富 14断块CO2 混相驱的成功为提高复杂小断块油藏采收率和丰富国内三次采油技术提供了重要的依据。

低渗油藏水驱后CO_2潜力评价及注采方式优选

针对延长油田乔家洼区块由于基质致密和非均质性严重造成注水开发效果差的问题,通过开展CO2室内驱油实验,在水驱基础上分别对连续气驱和气水交替驱驱油潜力进行评价,并对气水交替驱流体注入速度、段塞尺寸及气水比等注入参数进行优化。同时,对区块采用水驱、优化井网后水驱、利用优化的CO2驱注入参数开展气驱和注气5年后转气水交替驱4种开发方案,进行数值模拟产量预测。实验结果表明,CO2驱在目标区块高含水后有着较大驱油潜力,连续气驱和气水交替驱分别在水驱基础上可提高采收率8.43%和20.95%;气水交替注入方式下采收率随各注入参数的增大均呈先增加后降低的趋势,最佳注入速度、最佳注入段塞尺寸和最佳气水比分别为0.73mL/min、0.1PV和1∶1。数值模拟结果表明:优化井网后水驱、连续气驱和注气5年后转气水交替驱3种方案在开发15年后,分别可以在原水驱方案基础上提高采收率0.77%、13.81%和12.98%,建议采用注气5年后转气水交替驱方案进行生产。

鄂尔多斯盆地低渗透油藏水氮气交注非混相驱影响因素研究

目的找出影响鄂尔多斯盆地低渗透油藏水氮气交注非混相驱提高采收率技术的影响因素,为优化现场实施方案提供依据。方法在室内模拟油藏条件,通过物理模拟实验和理论研究分析注入方式、气水比和段塞数对低渗透油藏水氮气交注非混相驱的影响程度。结果先气驱再进行水氮气交注非混相驱的最终驱油效率要比先水驱再进行水氮气交注非混相驱高10.24%;在相同的氮气注入量下,气水比为1∶2、段塞数为2的注入方案驱油效果最好。结论水氮气交注非混相驱是鄂尔多斯盆地低渗透油藏水驱后改善驱油效果的一项有效措施;低渗透油藏实施超前注气不仅能够有效保持地层能量,实现低渗透油藏的高效开发,而且能够节约水资源。

延长油田长7致密油储层CO_2驱替特征

常规开发方式难以动用致密油储层流体,原油采出程度低.为探索更高效的驱油方式,以延长油田长7致密油储层为研究对象,选取实际储层样品,对比研究了单纯CO_2驱替与水驱替至含水率(体积分数)为60%时转CO_2-水交替驱替的长岩心驱替的实验研究.结果发现,单纯CO_2驱替和CO_2-水交替驱替2种方式的驱油效率明显高于单纯水驱替效率.其中,CO_2驱替效率可达50%以上;水驱替至含水率为60%时转CO_2-水交替驱替,驱油效率可达60%以上.通过核磁共振结合高速离心等测试手段对储层流体可动用性分析发现,储层中60%以上的流体赋存于纳米级空间,纳米级空间的可动用量仅有7%左右,储层流体极难动用. CO_2与原油间的物理化学作用起到了原位改质的效果,驱油效率得到了提升. CO_2-水交替存在造成贾敏效应,减缓水驱突进,强化纳米级低速渗流通道向储层必然渗流通道转变,驱油效率同样可得到提升.研究结果可为延长油田长7致密油储层CO_2驱替先导试验提供参考.