页岩气运移证据及其动态富集模式——以四川盆地南部深层页岩气为例

页岩气存在运移现象,但页岩气运移现象对页岩气富集的影响尚不明确。为了查明深层页岩气运移证据及其富集模式,以四川盆地南部下志留统龙马溪组深层页岩气藏为例,基于页岩气藏天然气地球化学特征、赋存于顺层低角度裂缝中方解石脉包裹体特征、储层孔隙结构,查明了页岩气运移通道及运移能力,并结合典型气藏解剖,划分了龙马溪组页岩气动态富集模式。研究结果表明:①页岩气藏流体势场指示运移方向与气体组分指示方向一致,表明页岩气存在运移现象,且赋存于顺层裂缝中的流体包裹体揭示了研究区龙马溪组页岩气存在2期运移,分别发生在生烃高峰和后期抬升阶段;②现今研究区龙马溪组页岩储层存在满足页岩气运移的孔隙,且龙马溪组页岩孔隙以满足菲克扩散的孔隙为主,其次为满足滑脱渗流的孔隙和满足达西渗流的孔隙;③页岩气运移对页岩气富集具有重要的影响,研究区可划分出高抬升过渡带富集型、断裂散失背斜过渡带富集型、断裂散失向斜核部富集型、高部位富集型、弱运移能力断裂散失型5种页岩气动态富集模式。结论认为,在地质历史时期,页岩气存在运移现象,多期次的运移现象决定了现今的页岩气富集程度与富集区的优选。

基于机器学习算法的深部页岩储层物性预测及有利勘探区优选

以四川盆地泸州区块龙马溪组页岩为例,在岩心物性测试与测井数据基础上,对比分析了支持向量回归算法(SVR)、梯度提升决策树(GDBT)和极端梯度提升算法(XGBoost)3种机器学习算法预测结果并优选出适宜的评价模型,实现了深部页岩储层物性预测与有利勘探区优选。结果显示:1)3种热门学习算法在深部页岩储层物性预测方面均具有良好的应用效果,经过对比,认为GDBT为预测研究区深部页岩储层孔隙度最适宜的算法,XGBoost为预测研究区深部页岩储层渗透率最适宜的算法;2)基于上述优选模型,泸州区块龙马溪组页岩孔隙度为2.67%~9.67%,平均孔隙度为4.88%,渗透率为3.22~28.63μD,平均渗透率为11.34μD;3)依据龙马溪组页岩储层物性与含气量,可划分出7个I类有利区,3个Ⅱ类有利区和4个Ⅲ类有利区。该研究成果基于研究区实际情况,可为研究区与类似区块页岩储层评价及有利区预测提供参考。

页岩定面射孔水力裂缝起裂特征探索及应用

定面射孔是近年来针对非常规油气井体积压裂发展起来的一项新型射孔技术。该技术改变了常规螺旋布弹方式,采用特制超大孔径射孔弹和特殊布弹方式,射孔后在其方向上形成一个扇面。该射孔工艺在致密油气水平井已得到广泛应用,但在页岩气水平井压裂上还相对较少。文中开展室内物理模拟实验,探索了定面射孔对施工压力、水力裂缝起裂、延伸及形态特征的影响。该技术在国内首次应用于四川盆地某页岩气水平井,并利用软件模拟对定面射孔压后水力裂缝进行分析。现场应用结果及评价结果表明,相对于常规螺旋射孔,该技术有利于降低近井筒孔眼摩阻,也有利于提高页岩压后水力裂缝缝网体积。

四川盆地龙马溪组深层页岩储层压力与含气量动态演化过程

四川盆地五峰—龙马溪组页岩储层超压发育,但超压演化过程中页岩气含气量的变化特征尚不清楚。为了探明龙马溪组页岩储层压力与含气量动态演化过程,以四川盆地泸州区块L3H1为例,借助于盆地模拟、流体包裹体测温、激光拉曼光谱等测试,重建了泸州区块异常压力演化过程,并结合古温压条件,揭示了泸州区块龙马溪组页岩储层压力与含气量动态演化过程。结果显示:L3H1井流体包裹体均一温度为98.6~214.4℃,均值为155.41℃,冰点温度为–9.3~–2.2℃,均值为–4.97℃,甲烷激光拉曼峰位位移为2910.13~2910.57 cm^(-1),均值为2910.32 cm^(-1),甲烷密度为0.262~0.284 g/cm^(3),均值为0.275g/cm^(3);L3H1井压力演化过程与有机质生排烃密切相关,储层压力随有机质成熟度增加而增加,在最大古埋深时达到最大压力,为189.39 MPa,压力系数为2.48,在地层抬升阶段发生泄压;L3H1井含气量演化可分为3个阶段,湿气阶段随有机质成熟增加,吸附气量与游离气含量增加,水溶气含量具有先增加后减少特点,干气阶段随成熟度增加,游离气含量逐渐增加,吸附气含量随成熟度先增加后急剧减少,水溶气含量持续下降,抬升阶段吸附气含量逐渐增加,水溶气和游离气含量逐渐减少。

Establishment and application of the anisotropic shale-rock physical model in the observation coordinate system

No shale-rock physical model has been established in the observation coordinate system.To this end,this paper carried out anisotropic wave velocity tests on shale rock and compared the Thomsen,Daley,and Berryman solutions to characterize anisotropic acoustic wave velocity.Finally,the Daley solution was selected.Based on basic rock physical models,such as SCA and DEM methods,and combined with the Daley solution,an anisotropic shale-rock physical model was established in the observation coordinate system and applied in Well B1 in the Luzhou area,Sichuan Basin.Our research conclusions were as follows:1.for the samples from the same core,the P-wave velocities in three directions were in the order VP11>VP45>VP33,shear wave velocity VS11 was the largest,but VS33 and VS45 did not follow the law of Vs33>Vs45 for some samples;2.the Daley solution,which not only considers the accuracy requirements but also has a complete expression of P-,SV-,and SH-waves,is most suitable for characterization of anisotropic wave velocity in this study area;3.the rock physical model constructed in the observation coordinate system has high accuracy,in which the absolute value of the relative error of the P-wave slowness was between 0%and 5.05%(0.55%on average),and that of shear-wave slowness was between 0%and 6.05%(0.59%on average);4.the acoustic waves recorded in Well B1 in the observation coordinate system were very different from those in the constitutive coordinate system.The relative difference of the P-wave was between 6.76%and 30.84%(14.68%on average),and that of the S-wave was between 7.00%and 23.44%(13.99%on average).The acoustic slowness measured in the observation coordinate system,such as in a deviated well or a horizontal well section,must be converted to the constitutive coordinate system before it can be used in subsequent engineering applications;5.the anisotropic shale-rock physical model built in the observation coordinate system proposed in this paper can provide basic data and guidance for subsequent pore pressure prediction,geomechanical modeling,and fracturing stimulation design for deviated and horizontal wells.