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101.
以胜利油区孤岛油田11J11密井网区曲流河储层为例,在曲流河野外露头和现代沉积原型模型研究成果的基础上,应用岩心、测井及动态等资料,探索了一套曲流河地下储层构型分析方法。在基于构型分析的精细等时地层对比及单井构型要素解释的基础上,采用“层次分析”和“模式拟合”的研究思路,按复合曲流带、单一曲流带、单一点坝以及点坝内部侧积体的4个层次进行模式拟合,对曲流河各级次构型单元内部结构进行系统分析。拟合结果既符合曲流河沉积成因理论,又与研究区动态资料吻合,说明研究成果是可靠的,由此建立了真正意义上的三维储层构型模型,再现了曲流河点坝内部泥质侧积层空间分布特征,为分析油田开发后期储层构型控制的剩余油分布规律提供了科学依据,该方法对类似油田精细储层研究有较好的借鉴作用,并能推广应用。
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102.
103.
安塞油田延长组储集层特征及物性影响因素分析 总被引:14,自引:0,他引:14
通过研究区内大量岩心铸体薄片及物性等资料分析,对安塞油田延长组主要产油层组长2和长6储集层的岩石学特征、孔渗特征及孔隙类型等进行了深入研究,分析了影响储层储集性能的主要因素。结果表明:三角洲平原亚相沉积的长2储层和三角洲前缘亚相沉积的长6储层均具矿物成熟度低而结构成熟度高的岩石学特点,但长2成分成熟度稍优于长6,长2孔隙类型为碳酸盐溶孔-长石溶孔-原生粒间孔组合,物性表现为中孔、低渗型;而长6孔隙类型为长石溶孔-原生粒间孔-浊沸石溶孔组合。物性特点为中孔、特低渗型。沉积环境、岩石成分及粒径、填隙物成分及含量、成岩作用等是影响物性的主要因素。 相似文献
104.
针对胜利油田埕岛海域海床土体强度的非均匀性和可能引起的海底管线差异沉降破坏,提出1种海底管线差异沉降安全性分析方法.具体介绍差异沉降产生的原因,通过分析管线的受力状态,建立管线因差异沉降引起的附加应力的表达式.针对黄河水下三角洲埕岛油田常见的3种规格管线,建立不同土质条件下的管线附加应力表格,方便工程师查询.考虑附加应力和流体对管线的应力,与管线材料的允许应力比较,可以判断管线的安全性. 相似文献
105.
靖安油田盘古梁长6油藏地质建模研究 总被引:1,自引:0,他引:1
建立能正确反映靖安油田盘古梁长6油藏地质特征的地质模型,通过对地层格架、沉积微相、骨架砂体、物性参数和储层非均质性的分析研究,借助GMSS地质建模软件,建立了确定型精细三维地质模型。所建立的构造、砂体、属性参数模型对该油藏的地质特征有了进一步认识,为油藏的高效开发提供了依据。 相似文献
106.
107.
胜利油田近海及沿岸地区东北大风及风暴潮分析预报 总被引:1,自引:0,他引:1
对产生影响胜利油田近海及沿岸地区东北大风及风暴潮灾害的两大类天气系统进行了具体分析,分别给出了冷锋配合江淮气旋产生东北大风及风暴潮的三种环流形势和两类影响胜利油田热带气旋移动路径及其预报着眼点。 相似文献
108.
The geochemical characteristics and origin of crude oils in the Kekeya Oilfield,Xinjiang, China 总被引:2,自引:2,他引:0
GC/MS and GC/MS/MS techniques were employed to describe the characteristics of biomarker assemblages in two sets of hydrocarbon source rocks, Jurassic and Permian, in southwestern Tarim, and the parameters for the classification of the two sets of hydrocarbon source rocks have been established. It is found that diahopane and C30-unknown terpane are abundant in Permian samples, the contents of diahopane in Jurassic samples are relatively low, and terpenoids have been detected in Jurassic samples but not in Permian source rock samples. Kekeya crude oils are abundant in diahopane and C30-unknown terpane. The results of fine oil-rock correlation indicated that Kekeya crude oils were derived mainly from the Permian hydrocarbon source rocks. However, a small amount of diterpenoid was detected in the crude oils, indicating that the Jurassic hydrocarbon source rocks also made a certain contribution to Kekeya crude oils. 相似文献
109.
110.
Distribution of the Ordovician Fluid in the Tahe Oilfield and Dynamic Response of Cave System S48 to Exploitation 总被引:2,自引:1,他引:1
The Tahe Oilfield is a complex petroleum reservoir of Ordovician carbonate formation and made up of spatially overlapping fracture-cavity units. The oilfield is controlled by a cave system resulting from structure-karst cyclic sedimentation. Due to significant heterogeneity of the reservoir, the distribution of oil and water is complicated. Horizontally, a fresh water zone due to meteoric water can be found in the north part of the Akekule uplift. A marginal freshening zone caused by water released from mudstone compaction is found at the bottom of the southern slope. Located in a crossformational flow discharge zone caused by centripetal and the centrifugal flows, the main part of the Tahe Oilfield, featuring high salinity and concentrations of CI^- and K^++Na^+, is favorable for accumulation of hydrocarbon. Three types of formation water in the Tahe Ordovician reservoir are identified: (1) residual water at the bottom of the cave after oil and gas displacement, (2) residual water in fractures/pores around the cave after oil and gas displacement, and (3) interlayer water below reservoirs. The cave system is the main reservoir space, which consists of the main cave, branch caves and depressions between caves. Taking Cave System S48 in the Ordovician reservoir as an example, the paper analyzes the fluid distribution and exploitation performance in the cave system. Owing to evaporation of groundwater during cross-formational flow, the central part of the main cave, where oil layers are thick and there is a high degree of displacement, is characterized by high salinity and Br^- concentration. With high potential and a long stable production period, most wells in the central part of the main cave have a long water-free oil production period. Even after water breakthrough, the water content has a slow or stepwise increase and the hydrochemistral characteristics of the produced water in the central part of the main cave are uniform. From the center to the edge of the main cave, displacement and enri 相似文献