矿物学分布非均质性对酸压裂效率的影响

Xiao Jin, D. Zhu, A. Hill, D. McDuff
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引用次数: 12

摘要

创造足够和持续的裂缝导流能力直接有助于酸压裂处理的成功。地层岩石的渗透率和矿物学分布在形成能够承受高闭合应力的非均匀蚀刻表面方面起着重要作用。先前的研究表明,根据地层岩石的性质和酸化条件(酸选择、地层温度、注入速率和接触时间),可以产生一系列蚀刻模式(粗糙度、均匀性、通道性),从而决定最终的裂缝导流能力。不溶性矿物及其分布可以完全改变酸压裂的效果。然而,大多数实验研究使用的都是均匀的岩石样本,如印第安纳石灰石,这并不代表碳酸盐岩的高度非均质特征。这项工作研究了非均质性,更重要的是,不溶性岩石的分布,对酸性裂缝导流能力的影响。在本研究中,我们对均质印第安纳石灰岩样品和非均质碳酸盐岩样品进行了酸压裂实验。印第安纳州的石灰石测试作为基准。高非均质碳酸盐岩样品沿封闭天然裂缝含有石英等多种不溶性矿物和多种粘土。这些矿物以与流动方向相关的条纹或较小的结核的形式分布。在对岩石样品进行酸化后,这些矿物作为矿柱,在高闭合应力下显著降低了电导率的下降速度。通过x射线衍射(XRD)和x射线荧光(XRF)测试,确定了裂缝表面不同矿物的类型和位置。通过比较酸化测试后的表面扫描结果与导电性测试后的扫描结果,表面剖面仪也被用于将导电性作为矿物分布的函数进行关联。采用考虑地统计相关参数的理论模型对实验结果进行拟合和理解。研究结果表明,具有较高力学性能的不溶性矿物在高闭合应力下不会被压碎,导致电导率随闭合应力的增加而下降的幅度较小。如果酸蚀产生足够的导电性,岩石样品可以承受较高的闭合应力,与印第安纳石灰石样品相比,下降率要低得多。与流动方向相关的不溶性矿物条纹的裂缝表面提供了能够在高闭合应力下保持导电性的好处,但不一定是高初始导电性。利用具有相关长度的裂缝导电性模型,我们匹配了非均质样品的裂缝导电性行为。与与流动方向相关的裂缝表面相比,与流动方向相关的裂缝表面具有矿物条纹,可以显着提高酸压裂导流能力。研究结果表明,利用不溶性矿物沿裂缝表面的分布可以优化裂缝导流能力,并表明了酸压裂成功的重要考虑因素。
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Effects of Heterogeneity in Mineralogy Distribution on Acid Fracturing Efficiency
Creating sufficient and sustained fracture conductivity contributes directly to the success of acid fracturing treatments. The permeability and mineralogy distributions of formation rocks play significant roles in creating non-uniformly etched surfaces that can withstand high closure stress. Previous studies showed that depending on the properties of formation rock and acidizing conditions (acid selection, formation temperature, injection rate and contact time), a wide range of etching patterns (roughness, uniform, channeling) could be created that can dictate the resultant fracture conductivity. Insoluble minerals and their distribution can completely change the outcomes of acid fracturing treatments. However, most experimental studies use homogeneous rock samples such as Indiana limestones that do not represent the highly-heterogeneous features of carbonate rocks. This work studies the effect of heterogeneity, and more importantly, the distribution of insoluble rock, on acid fracture conductivity. In this research, we conducted acid fracturing experiments using both homogeneous Indiana limestone samples and heterogeneous carbonate rock samples. The Indiana limestone tests served as a baseline. The highly-heterogeneous carbonate rock samples contain several types of insoluble minerals such as quartz and various types of clays along sealed natural fractures. These minerals are distributed in the form of streaks correlated against the flow direction, or as smaller nodules. After acidizing the rock samples, these minerals acted as pillars that significantly reduced conductivity decline rate at high closure stresses. Both X-ray diffraction (XRD) and X-ray fluorescence (XRF) tests were done to pinpoint the type and location of different minerals on the fracture surfaces. A surface profilometer was also used to correlate conductivity as a function of mineralogy distribution by comparing the surface scans from after the acidizing test to the scans after the conductivity test. Theoretical models considering geostatistical correlation parameters were used to match and understand the experimental results. Results of this study showed that insoluble minerals with higher mechanical properties were not crushed at high closure stress, resulting in a less steep conductivity decline with increasing closure stress. If the acid etching creates enough conductivity, the rock sample can sustain a higher closure stress with a much lower decline rate compared with Indiana limestone samples. Fracture surfaces with insoluble mineral streaks correlated against the flow direction offer the benefit of being able to maintain conductivity at high closure stress, but not necessarily high initial conductivity. Using a fracture conductivity model with correlation length, we matched the fracture conductivity behavior for the heterogeneous samples. Fracture surfaces with mineral streaks correlated with the flow direction could increase acid fracturing conductivity significantly as compared to the case when the streak is correlated against the flow direction. The results of the study show that fracture conductivity can be optimized by taking advantage of the distribution of insoluble minerals along the fracture surface and demonstrate the important considerations to make the acid fracturing treatment successful.
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