成岩作用对滇东地区筇竹寺组页岩孔隙特征的控制机制

基于滇东地区筇竹寺组钻井岩样压汞实验数据,并结合X射线衍射及SEM观察,从成岩作用入手研究其对页岩孔隙特征的控制。结果表明:筇竹寺组页岩孔径从超大孔至微孔均有发育,过渡孔及微孔是孔容及孔比表面积的主要贡献者;压汞孔隙度与TOC含量及黏土矿物含量呈正相关关系,与脆性矿物含量呈负相关关系;基于进汞曲线形态及孔径分布,将本区页岩气储层孔隙结构划分为退汞效率低,孔隙联通性好的S型,及退汞效率较高,孔隙联通性较好的反S型。受控于成岩作用中高岭石的伊利石化,伊利石继承高岭石孔隙结构特征,随着含量的增加,开放联通型中孔、过渡孔及微孔孔容会迅速增加,孔隙度增大;但成岩过程中产生的溶解硅重结晶使部分孔隙受到石英的胶结及堵塞,成为封闭孔及半封闭孔,随着石英含量的增加,孔隙度减小,两者共同作用,形成了本区筇竹寺组页岩S型及反S型孔隙结构类型。

川西南筇竹寺组页岩气复合地质导向方法研究

目前针对川西南寒武系筇竹寺组页岩气的勘探已取得可喜的油气成果,揭示了筇竹寺组页岩气藏具有良好的勘探开发前景。文章总结富气页岩储层地质的测井响应特征,利用岩心刻度、元素录井、岩屑伽马能谱录井、随钻测量等方法建立了岩石组分含量、孔隙度、有机碳含量和含气量、脆性随钻评价模型,形成了一套适用于筇竹寺组页岩气储层的复合地质导向方法,并在川西南地区筇竹寺组页岩气勘探中取得了良好的应用效果。

川南地区筇竹寺组页岩微观孔隙结构特征及其影响因素

页岩微观孔隙结构是影响页岩气储层储集能力的重要因素。为评价川南地区下寒武统筇竹寺组页岩性质,基于井下岩心样品、钻井资料,运用普通扫描电镜和氩离子抛光—场发射扫描电镜观测、Image J2x软件分析、低温CO_2和N_2吸附、高压压汞实验方法,对川南地区筇竹寺组页岩气微观孔隙成因类型、孔隙结构特征及其影响因素进行了研究。研究结果表明,川南地区下寒武统筇竹寺组页岩孔隙度为0.25%~5.80%,平均为2.49%;发育多种成因类型微观孔隙,以粒间孔为主,粒内孔、有机质孔和微裂缝次之,页岩微观孔隙总面孔率为3.58%~5.92%;川南地区筇竹寺组页岩总孔容为(2.86~12.55)×10^(-3)m L/g,总比表面积为2.727~21.992 m^2/g,孔径主要分布于0.30~1.00 nm、2.5~4.7 nm和55~70 nm这三个区间,微孔(<2 nm)和介孔(2~50 nm)是筇竹寺组页岩气储集空间的主体,孔隙结构形态主要为圆孔、楔形孔、平板狭缝型孔和混合型孔结构。页岩孔隙度及总比表面积与TOC、脆性矿物含量呈正相关关系,页岩微孔孔容及比表面积与TOC呈正相关关系,页岩孔隙度、总孔容及总比表面积与R0、粘土矿物含量呈负相关关系。

威远地区早古生代筇竹寺组页岩储层有机碳预测方法研究

总有机碳含量(TOC)是评价页岩生烃能力的关键性指标,岩心样品测试仅能获得离散的TOC含量,且成本较高。基于页岩在常规测井上的响应特征,运用多元回归分析法、拓展ΔlgR法、RBF神经网络法对威远地区筇竹寺组页岩TOC含量进行预测。结果表明:①优质页岩测井曲线响应特征通常表现为“四高两低一扩”,即高自然伽马、高电阻率、高声波时差、高中子、低密度、低光电吸收截面指数、井径扩径,同时测井曲线响应特征还受矿物成分的影响;②ΔlgR法运用于较深页岩储层的TOC预测时,需根据研究区具体地质情况进行合理的改进;③相比多元回归分析法和拓展ΔlgR法,RBF神经网络法能通过空间变换较精确的描述有机碳与测井参数的非线性关系,使预测的有机碳与实测值拟合度高,预测效果最好,为研究区最佳有机碳预测方法。

Shales in the Qiongzhusi and Wufeng–Longmaxi Formations:a rock-physics model and analysis of the effective pore aspect ratio

The shales of the Qiongzhusi Formation and Wufeng-Longmaxi Formations at Sichuan Basin and surrounding areas are presently the most important stratigraphic horizons for shale gas exploration and development in China. However, the regional characteristics of the seismic elastic properties need to be better determined. The ultrasonic velocities of shale samples were measured under dry conditions and the relations between elastic properties and petrology were systemically analyzed. The results suggest that 1） the effective porosity is positively correlated with clay content but negatively correlated with brittle minerals, 2） the dry shale matrix consists of clays, quartz, feldspars, and carbonates, and 3） organic matter and pyrite are in the pore spaces, weakly coupled with the shale matrix. Thus, by assuming that all connected pores are only present in the clay minerals and using the Gassmann substitution method to calculate the elastic effect of organic matter and pyrite in the pores, a relatively simple rock-physics model was constructed by combining the self-consistent approximation （SCA）, the differential effective medium （DEM）, and Gassmann＇s equation. In addition, the effective pore aspect ratio was adopted from the sample averages or estimated from the carbonate content. The proposed model was used to predict the P-wave velocities and generally matched the ultrasonic measurements very well.