Profile improvement during CO_2 flooding in ultra-low permeability reservoirs

Gas flooding such as CO2 flooding may be effectively applied to ultra-low permeability reservoirs, but gas channeling is inevitable due to low viscosity and high mobility of gas and formation heterogeneity. In order to mitigate or prevent gas channeling, ethylenediamine is chosen for permeability profile control. The reaction mechanism of ethylenediamine with CO2, injection performance, swept volume, and enhanced oil recovery were systematically evaluated. The reaction product of ethylenediamine and CO2 was a white solid or a light yellow viscous liquid, which would mitigate or prevent gas channeling. Also, ethylenediamine could be easily injected into ultra-low permeability cores at high temperature with protective ethanol slugs. The core was swept by injection of 0.3 PV ethylenediamine. Oil displacement tests performed on heterogeneous models with closed fractures, oil recovery was significantly enhanced with injection of ethylenediamine. Experimental results showed that using ethylenediamine to plug high permeability layers would provide a new research idea for the gas injection in fractured, heterogeneous and ultra-low permeability reservoirs. This technology has the potential to be widely applied in oilfields.

The control effect of low-amplitude structure on oil-gaswater enrichment and development performance of ultra-low permeability reservoirs

Based on drilling, logging, test production and dynamic monitoring data, the control effects of low-amplitude structure on hydrocarbon accumulation and development performance of ultra-low permeability reservoirs were discussed by using the methods of dense well pattern, multi-factor geological modeling, macro and micro analysis and static and dynamic analysis. The results show that the low-amplitude structure always had a significant control and influence on the distribution and accumulation of original hydrocarbon and water and the evolution trend of water flooding performance in ultra-low permeability reservoirs, and it was not only the direction of oil and gas migration, but also a favorable place for relative accumulation of oil and gas. The controlling effect of low-amplitude structure on ultra-low permeability reservoir mainly depended on its tectonic amplitude and scale;the larger the tectonic amplitude and scale, and the higher the tectonic position of the low amplitude structure, the better the reservoir characteristic parameters, oil and gas enrichment degree and development effect, and the larger the spatial scope it controlled and influenced;water cut and oil well output always fluctuated orderly with the height of the low-amplitude structure;the dynamic response of waterflooding was closely related to the relative structural position of the injection and production wells;the injected water always advanced to the low-lying area of the structure first and then moved up to the high-lying area of the structure gradually;with the continuous expansion of the flooded area, part of the oil and gas in the low-lying part of the structure was forced to be distributed to the high part of the structure, resulting in a new oil and gas enrichment, so that the dynamic reserves of oil wells in the high part increased, and the production capacity remained stable.

Method of moderate water injection and its application in ultra-low permeability oil reservoirs of Yanchang Oilfield, NW China

To explore the method of improving development effect and solving the problem of water breakthrough and water out for ultralow permeability fractured reservoirs, an indoor evaluation method of dynamic imbibition for fracture-matrix system was established taking the Chang 8 reservoir in southern Yanchang Oilfield as a research target. Key factors for the imbibition effect were obtained, an imbibition's rate expression was obtained, a model considering the double effects of imbibition-displacement was built and optimal injection and production parameters for the research area were obtained as well. The results show that an optimum displacement rate that maximizes the oil displacement efficiency exists in the water displacing oil process, and the optimal displacing rate becomes smaller as the permeability decreases. The imbibition displacement efficiency increases as the reservoir quality index and water wettability index of rock become bigger. But the larger the initial water saturation or oil-water viscosity ratio is, the smaller the imbibition displacement efficiency is. The optimal injection-production ratio for the Chang 8 reservoir of southern Yanchang Oilfield is 0.95, and the predicted recovery is 17.2% when the water cut is 95%, it is 2.9% higher than the recovery of conventional injection-production ratio 1.2. By using the moderate water injection technique based on the double effects of imbibition-displacement mechanism, the water injection development effect for the ultra-low permeability fractured reservoirs can be improved significantly.

A quantitative evaluation for well pattern adaptability in ultra-low permeability oil reservoirs:A case study of Triassic Chang 6 and Chang 8 reservoirs in Ordos Basin

Based on the previous studies and development practice in recent 10 years, a quantitative evaluation method for the adaptability of well patterns to ultra-low permeability reservoirs was established using cluster analysis and gray correlation method, and it includes 10 evaluation parameters in the four aspects of optimal evaluation parameters, determination of weights for evaluation parameters, development stage division, and determination of classification coefficients. This evaluation method was used to evaluate the well pattern adaptability of 13 main ultra-low permeability reservoirs in Triassic Chang 6 and Chang 8 of Ordos Basin. Three basic understandings were obtained: Firstly, the well pattern for ultra-low permeability type-I reservoirs has generally good adaptability, with proper well pattern forms and well pattern parameters. Secondly, square inverted nine-spot well pattern is suitable for reservoirs with no fractures; rhombic inverted nine-spot injection pattern is suitable for reservoirs with some fractures; and rectangular well pattern is suitable for reservoirs with rich fractures. Thirdly, for the ultra-low permeability type-Ⅱ and type-Ⅲ reservoirs, with the principles of well pattern form determination, the row spacing needs to be optimized further to improve the level of development of such reservoirs.

The tectonic fracture modeling of an ultra-low permeability sandstone reservoir based on an outcrop analogy: A case study in the Wangyao Oilfield of Ordos Basin, China

Due to inherent limits of data acquisition and geophysical data resolution, there are large uncertainties in the characterization of subsurface fractures. However, outcrop analogies can provide qualitative and quantitative information on a large number of fractures, based on which the accuracy of subsurface fracture characterization can be improved. Here we take the tectonic fracture modeling of an ultra-low permeability sandstone reservoir based on an outcrop analogy, a case study of the Chang6t~ Formation of the Upper Triassic Yanchang Group of the Wangyao Oilfield in the Ordos Basin of China. An outcrop at the edge of the basin is a suitable analog for the reservoir, but the prerequisite is that they must have equivalent previous stress fields, similar final structural characteristics, relative timing and an identical depositional environment and diagenesis. The relationship among fracture density, rock type and bed thickness based on the outcrop is one of the most important fracture distribution models, and can be used to interpret fracture density in individual wells quantitatively. Fracture orientation, dip, geometry and scale, also should be described and measured in the outcrop, and can be used together with structure restoration and single well fracture density interpretation to guide fracture intensity prediction on bed surfaces and to constrain the construction of the 3D fracture geometry model of the subsurface reservoir. The application of the above principles shows the outcrop-based tectonic fracture models of the target ultra-low permeability sandstone reservoir are consistent with fractures inferred from microseismic interpretation and tracer tests. This illustrated that the fracture modeling based on the outcrop analogy is reliable and can reduce the uncertainty in stochastic fracture modeling.

INVESTIGATION AND APPLICATION ON GAS-DRIVE DEVELOPMENT IN ULTRA-LOW PERMEABILITY RESERVOIRS

To select a proper displacement medium with the purpose of developing ultra-low permeability reservoirs both effectively and economically, three kinds of gases, including CO2, NG and N2, are studied through physical modeling and numerical simulation under the specified reservoir conditions. The results indicate that the oil recovery through water injection is relatively low in ultra-low permeability reservoirs, where the water breaks through early and the water cut rises rapidly. Gas injection can enhance the production, of which the gas-drive efficiency depends on the injection pressure and the gas itself. CO2 is proved to be the best one after comprehensive consideration of the recovery speed, the overall recovery efficiency and the time needed for gas to break through. The pressure of CO2 injection in the field experiments is lower, compared with that of water-drive. The injectivity index of CO2 is 7.2 times as high as that of water, and the oil production of the test well group increases by about 4 t/d.

基于GA-BP神经网络的特低渗砂岩油藏水平井产能预测——以子长油田长6油藏为例

为明确子长油田特低渗透砂岩油藏水平井产能主控因素,并提高BP神经网络产能预测模型准确率,运用灰色关联方法厘定影响子长油田长6油藏水平井压后产能的主控因素,并建立遗传算法优化BP神经网络的特低渗透砂岩油藏水平井产能预测模型,以子长油田长6油藏92口压裂水平井数据进行训练和验证,对比分析标准BP神经网络与GA-BP神经网络模型预测结果和误差。结果表明,地质因素和工程因素对特低渗砂岩油藏水平井产能影响程度最大,尤其是压裂段数、渗透率和孔隙度影响最为明显;GA-BP模型各项参数的预测误差均远小于标准BP模型的预测误差,平均绝对误差仅为0.76 t/d,比标准BP模型降低了75.00%;GA-BP神经网络模型具有预测结果准确度高、高效可行的特点。利用GA-BP神经网络模型预测特低渗砂岩油藏水平井产能,为制定合理开发决策提供依据,可以有效地指导现场生产。

The distribution rule and seepage effect of the fractures in the ultra-low permeability sandstone reservoir in east Gansu Province,Ordos Basin

To study the impact of the fractures on development in the ultra-low permeability sandstone reservoir of the Yangchang Formation of the Upper Triassic in the Ordos Basin,data on outcrops,cores,slices,well logging and experiments are utilized to analyze the cause of the formation of the fractures,their distribution rules and the control factors and discuss the seepage flow effect of the fractures. In the studied area developed chiefly high-angle tectonic fractures and horizontal bedding fractures,inter-granular fractures and grain boundary fractures as well. Grain boundary fractures and intragranular fractures serve as vital channels linking intragranular pores and intergranular solution pores in the reservoir matrix,thus providing a good connectivity between the pores in the ultra-low perme-ability sandstone reservoir. The formation of fractures and their distribution are influenced by such external and internal factors as the palaeo-tectonic stress field,the reservoir lithological character,the thickness of the rock layer and the anisotropy of a layer. The present-day stress field influences the preservative state of fractures and their seepage flow effect. Under the tec-tonic effect of both the Yanshan and Himalayan periods,in this region four sets of fractures are distributed,respectively assuming the NE-SW,NW-SE,nearly E-W and nearly S-N orientations,but,due to the effect of the rock anisotropy of the rock formation,in some part of it two groups of nearly orthogonal fractures are chiefly distributed. Under the effect of the present-day stress field,the fractures that assume the NE-SW direction have a good connectivity,big apertures,a high permeability and a minimum starting pressure,all of which are main advantages of the seepage fractures in this region. With the development of oilfields,the permeability of the fractures of dif-ferent directions will have a dynamic change.

用于提高低-特低渗透油气藏改造效果的缝网压裂技术

在对低孔隙度、低渗透-特低渗透砂岩油气藏压裂中,由于储层基质向裂缝的供油气能力较差,仅靠单一的压裂主缝(不管缝有多长、导流能力有多高)很难取得预期的增产效果。因此,提出了适合低孔隙度、低渗透、不含天然裂缝储层的"缝网压裂"技术。其核心思想是利用储层两个水平主应力差值与裂缝延伸净压力的关系,实现远井地带(而不仅仅局限于近井筒区域)的"缝网"效果,增加储层基质向人工裂缝供油气能力,提高压裂增产改造效果。论述了"缝网压裂"技术的适用条件、工艺设计思路及应用方法。在此基础上,对"缝网压裂"的实现途径进行了探索,包括水平井及应用"层内液体爆炸"技术等。缝网压裂技术对理论和现场施工有重要的参考价值。

特超低渗砂岩油藏储层非均质性特征与成藏模式--以鄂尔多斯盆地西部延长组下组合为例

针对陆相碎屑岩特超低渗储层油气运聚成藏研究中存在的问题,选择鄂尔多斯盆地西部延长组下组合砂岩油藏储层为研究对象,分析其沉积结构构造、成岩作用与致密化过程的非均质性,认识储集空间的非均质性分布规律与石油充注特征。研究发现,河湖相特超低渗含油储层表现出较强的非均质性,含油砂岩与不含油砂岩交互成层,其中不含油砂岩可分为3类:钙质砂岩、富软颗粒砂岩和含水砂岩。其成岩过程迥然,其中钙质砂岩和富软颗粒砂岩的发育多与中—低级构型界面有关。含油砂岩中可识别出3期沥青,分别对应于晚侏罗世、早白垩世中期、早白垩世晚期的石油充注。以这些沥青为时间标志可将含油砂岩中的成岩过程划分为3期,并在含水砂岩中识别出对应的3期成岩过程。在钙质胶结和富软颗粒致密砂岩中,成岩作用主要发生在第1充注之前,其构成了储层内的隔夹层,并且往往形成不同层次、不完全封隔的似网状结构,影响甚至控制了后期的流体活动,引起后期成岩作用和油气充注过程的非均匀性。在储层非均质性及沉积构造分析、成岩过程及其与油气充注关系研究、古物性恢复的基础上,提出了结构非均质性特超低渗砂岩油藏成藏模式。

低渗-特低渗油藏非稳态油水相对渗透率计算模型

考虑低渗-特低渗储层多孔介质中油水渗流特征,建立考虑启动压力梯度、重力及毛管力影响的低渗-特低渗油藏非稳态油水相对渗透率计算模型,进行非稳态油水相对渗透率试验,计算不同影响因素下的油水相对渗透率曲线。结果表明,启动压力梯度作为油水渗流的阻力,对油水相对渗透率、储层压力、剩余油饱和度、产油及产水等影响最为显著,其次是重力,毛管力仅对油相相对渗透率有影响,对水相相对渗透率无影响。

特低渗透砂岩油田开发贾敏效应探讨--以鄂尔多斯盆地中生界延长组为例

鄂尔多斯盆地中生界延长组储层是典型的特低渗透砂岩储层,属于细孔微喉型,非均质性强,注水开发中贾敏效应异常强烈。通过微观砂岩模型水驱油实验发现贾敏效应是油田注水开发中不可忽视的阻力。实验中贾敏效应主要表现为:①水驱油过程中注水压力不断变化;②贾敏效应的循环作用;③油滴受贾敏效应作用无法运移;④贾敏效应致使水驱中油相渗透率急剧下降,水相渗透率缓慢上升。通过注采系统提高注水压力无法消除贾敏效应,因此在注水开发中要以预防贾敏效应为主。

特低-超低渗透砂岩储层微观孔喉特征与物性差异

为揭示特低-超低渗透砂岩储层微观孔隙结构与物性差异的关系,利用物性分析、铸体薄片、电镜扫描和高压压汞技术对鄂尔多斯盆地延长组3个典型的特低-超低渗透砂岩储层岩芯样品进行了实验测试。研究结果表明,特低-超低渗透砂岩储层喉道类型多样;但整体细小,对渗透率起主要贡献的较大喉道含量小是其物性较差的主要原因,同时微裂缝的发育也加剧了物性差异。统计对比发现,孔喉的分选系数在2.0～3.0,变异系数在0.15～0.3,对渗透率贡献相对较大。可见,储层物性是多种因素共同影响的综合反映,不同类型孔隙、喉道组成的储集空间,渗透率存在较大差异,物性差异正是孔喉特征差异的一种具体表现。

储层沉积-成岩过程中孔隙度参数演化的定量分析——以鄂尔多斯盆地沿25区块、庄40区块为例

分别对鄂尔多斯盆地中南部沿25、西南部庄40两区块延长组长6段砂岩的成岩作用和孔隙演化进行分析。研究表明,两区块目的层砂岩目前均处于中成岩B期。受成岩环境酸碱性的控制,沿25区块普遍发育浊沸石和绿泥石,其浊沸石溶蚀孔隙为有利的储集空间;庄40区块高岭石较为发育,长石、岩屑溶孔为有利的储集空间。成岩过程中孔隙度演化的定量研究表明,相似的成岩演化阶段,孔隙度的演化不同。两区块初始孔隙度相近,沿25区块为34.91%,庄40区块为33.42%。机械压实过程中,沿25区块孔隙损失率为40.33%;庄40区块孔隙损失率为55.45%。胶结、交代过程孔隙损失率:沿25区块为46.86%;庄40区块为36.51%。后期溶蚀过程中,沿25区块次生孔隙空间主要为浊沸石溶孔,次生溶孔占比例为55.76%;庄40区块次生孔隙空间主要为长石、岩屑溶孔,次生孔隙占比例为73.51%。两区块沉积-成岩过程中孔隙度参数演化的定量分析为优质储层的筛选及相关砂岩油田的滚动勘探提供借鉴。

特低渗透油藏启动压力现象研究--以侯市地区为例

三叠系延长组是长庆油田重要的油气储集层位,该套地层中存在启动压力现象。文中对该现象产生的原因作了初步探讨,认为启动压力的出现是多种因素综合作用的结果。同时以侯市地区的具体井位为例进行了分析测试。结果表明,侯市地区三叠系延长组地层存在明显的启动压力现象,且初步确定该地区启动压力梯度为0.327MPa/m。

特低渗透砂岩储层微裂缝特征及微裂缝参数的定量研究--以鄂尔多斯盆地沿25区块、庄40区块为例

对鄂尔多斯盆地沿25区块、庄40区块长6油藏进行精细描述,指出微裂缝对提高储层的渗流能力,提高特低渗油藏开发水平具有十分重要的意义。阐述了特低渗透储层的岩块、显裂缝系统及其各自特征,指出显裂缝大致由三组裂缝组成。研究认为:岩块系统包括基质和微裂缝两部分,微裂缝一般长度小于200μm,规模小;两区块特低渗储层微裂缝呈条带状展布,且呈平行或雁式排列,具有明显的方向性,条带性随着岩性的变化而变化;可将微裂缝划分为有效缝和无效缝,有效缝对渗流起作用,无效缝充填方解石,对渗流不起作用。微裂缝和基质的储、渗性能差别很大,沿25区块微裂缝的储集能力是基质的0.0377倍,渗流能力是基质的42倍;庄40区块微裂缝的储集能力是基质的0.0337倍,渗流能力是基质的78倍。

基于“岩石物理相-流动单元”测井响应定量评价特低渗透油藏优质储层——以延长油田东部油区长6油层组为例

岩石物理相和流动单元均可从不同角度表征储层的非均质性,鄂尔多斯盆地东部地区特低渗透储层非均质性极强,单独利用岩石物理相或流动单元对该地区进行储层评价会存在一定偏差。通过定性识别和定量划分,建立了"岩石物理相-流动单元"定量综合评价指标体系,并提出利用这一体系来定量评价优质储层。研究结果表明:一类、二类"岩石物理相-流动单元"具有较好的储集性能和渗流结构,由其圈定的近期可开发或评价后可开发的优质储层共49个,从而确定了含油甜点区的分布规律和延展方向。这一研究成果能兼顾岩石物理相对于油气富集的控制作用和流动单元的流动特性,可有效减小单独利用岩石物理相或流动单元筛选优质储层所造成的误差,现场应用效果较好,为研究区增储上产提供了有利井位和区域。

储层沉积-成岩过程中物性演化的主控因素

对鄂尔多斯盆地Y25、Zh40区块长6段储层的岩石学特征、微观孔隙结构、成岩作用等进行详细研究。研究发现,胶结作用对储层质量的影响具有双重作用。胶结作用一定程度上提高储层的抗压实能力,也为后期的次生溶蚀提供物质基础,但胶结物的产生也占据一定的孔隙空间。两区块储层成岩作用是物性演化的最主要控制因素,储层类型为次生低渗透储层(或成岩型低渗透储层)。Y25区块表现为早期胶结作用和后期的溶蚀作用强;Zh40区块表现为早期压实作用强,后期溶蚀作用、交代作用强。储层形成过程中物性演化的主要控制因素是沉积环境基础上,成岩场和构造应力场共同作用的结果。

特低-超低渗透油藏注水开发影响因素分析及储层吸水能力评价

为特低-超低渗透油藏选择合适开发方式以实现高效开发,建立了一种以注水井注入能力和采油井见效情况为标准的储层评价方法。在分析特低-超低渗透油藏储层敏感性及其影响因素的基础上,利用实际生产动态资料采用视吸水指数对注水井的储层吸水能力进行分级;根据视吸水指数与各测井曲线的相关性分析结果,建立储层分类图版,将储层分为3类,确定了各类储层的物性下限。不同油藏储层物性下限不同,这种差异主要受储层水敏性差异影响。通过建立水敏指数与各类储层渗透率下限关系图可知,水敏指数越高,注水开发储层渗透率下限越高,储层水敏指数与储层渗透率界限呈指数关系;根据各类储层的渗透率及水敏指数的分界线,可将特低-超低渗透油藏划分为3类储层区,Ⅰ、Ⅱ类储层较适合注水开发,Ⅲ类储层需要探索新的地层能量补充方式。

超低侵害油气层保护剂NPL-2的研制及应用

室内通过对骨架材料和聚合物成膜材料的优选,研制出了超低侵害油气层保护剂NPL-2,并评价了超低侵害钻井液对砂床及微裂缝的封堵效果。结果表明,NPL-2具有广谱的封堵承压能力,加入3%NPL-2的钻井液在粒径为0.45-0.90 mm的模拟砂床中的侵入深度小于5 cm,可以封堵0.4 mm的人造裂缝,2-4 min内形成的超低侵害泥饼承压能力大于10 MPa;用西部地区岩心进行渗透率恢复实验,渗透率恢复值达90%以上,具有良好的油气层保护能力;在高温高压条件下依然具有好的封堵承压能力,可用于深井复杂地层中。NPL-2在大古1井、AD7井、元坝5井等进行了现场应用,成功解决了长裸眼井段的承压问题,提高了钻井液的油气层保护效果。