Characterization of sedimentary and flow characteristics of shallow water delta front sand bodies: Xingshugang Oil Field, Daqing placanticline, Songliao Basin
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摘要: 针对目前相渗研究与砂体沉积特征结合程度较低的问题,综合利用连续取心井的岩心、测井资料、油藏条件下的相渗测试数据、粒度分析、扫描电镜以及压汞数据,对松辽盆地大庆长垣浅水三角洲前缘亚相中分流河道微相及席状砂微相的沉积及渗流特征进行研究,分析了油水两相流的相对渗透率在分流河道垂向上的变化,以及在席状砂外缘、中部和内缘位置的差异。控制分流河道砂体和席状砂开发程度的因素分别为垂向上的水油流度差异和平面渗流能力的非均质性。浅水三角洲分流河道主体垂向上的相渗形态变化不大,但水油流度差异使底部更易水淹,是造成井间剩余油形成的主要因素;席状砂沉积特征的平面差异使注入水更易沿外缘推进,是造成内缘及中部的储量动用程度低的主要因素。Abstract: The low degree of integration between relative permeability research and the sedimentary characteristics of sand bodies was studied. The sedimentary and flow characteristics of distributary channel microfacies and sheet sand microfacies in shallow water delta front subfacies in the Daqing placanticline of the Songliao Basin were characterized by using core and logging data of continuously cored wells, relative permeability test data, grain size analysis, scanning electron microscopy and mercury injection data under reservoir conditions. The vertical variation of distributary channels and the difference of the positions of the outer edge, middle and inner edge of sheet sand were analyzed. The factors controlling the development degree of distributary channel sand body and sheet sand are the difference of vertical oil-water fluidity and the heterogeneity of horizontal flow capacity, respectively. In the distributary channel microfacies of shallow water delta, the relative permeability varies little; however, the vertical oil-water fluidity makes the bottom more prone to flooding, which is the main factor causing the formation of residual oil between wells. The planar difference of sheet sand sedimentary characteristics makes it easier for the injected water to advance along the outer edge, which is the main factor causing the low recovery of the reserves in the inner edge and the middle.
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图 1 松辽盆地大庆长垣构造区域划分及取心井位置
Figure 1. Structural regional division and coring well location in Daqing placanticline, Songliao Basin
图 2 松辽盆地大庆长垣X取心井浅水三角洲水下分流河道砂岩心扫描图
Figure 2. Core photographs of underwater distributary channel in shallow water delta of X coring well, Daqing placanticline, Songliao Basin
图 3 松辽盆地大庆长垣X取心井浅水三角洲水下分流河道样品粒径分布及扫描电镜照片
Figure 3. Particle size distribution and scanning electron microscope photographs of samples from underwater distributary channel in shallow water delta of X coring well, Daqing placanticline, Songliao Basin
图 4 松辽盆地大庆长垣X取心井浅水三角洲水下分流河道样品相对渗透率及相渗比值随饱和度的关系
Figure 4. Relative permeability curves and relationship between water-oil fluidity ratio and water saturation of samples from underwater distributary channel in shallow water delta of X coring well, Daqing placanticline, Songliao Basin
图 5 松辽盆地大庆长垣X取心井浅水三角洲席状砂岩心扫描图
Figure 5. Core photographs of sheet sand in shallow water delta of X coring well, Daqing placanticline, Songliao Basin
图 6 松辽盆地大庆长垣X取心井浅水三角洲席状砂样品粒径分布及扫描电镜照片
Figure 6. Particle size distribution of samples from sheet sand in shallow water delta of X coring well, Daqing placanticline, Songliao Basin
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