高孔隙压力页岩油区水平层理面裂缝对储层产液的影响

D. A. Arias Ortiz, Lukasz Klimkowski, T. Finkbeiner, T. Patzek
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引用次数: 0

摘要

大规模水力压裂改造在页岩储层中形成了复杂的诱导裂缝系统。以超压和小差应力为特征的泥岩储层复杂性增加。这种条件有利于诱导的垂直水力裂缝与机械弱层理面之间的相互作用。当这些平面容易分层时,它们可能会水力刺激较大的水平裂缝成分。在这种情况下,弱层理面在水力裂缝扩展过程中是至关重要的,会影响裂缝的几何形状和相关的油气产量。在以高孔隙压力为特征的多层泥岩储层中,研究了受刺激的机械弱水平层理面对储层流体产量的影响。我们提出了两种理想化但可行的几何形状(“裂缝场景”),据报道,它们出现在一些超压页岩区。我们的参考场景仅包括垂直和平面水力诱导裂缝。在第二个几何形状中,我们添加了与垂直水力裂缝相交的受激水平层理面裂缝。接下来,我们将预先确定的裂缝几何形状整合到商用油藏模拟器(CMG-IMEX)中,并评估井筒流动性能。最后,对水平裂缝闭合机理、水平裂缝位置和数量、垂向裂缝渗透率降低等因素进行敏感性分析。结果表明,大型水平裂缝影响油气产量。认为水平裂缝压缩性和垂向水力裂缝渗透率是储层模拟的关键参数。与参考情景相比,假设存在高导流性垂直水力裂缝,无支撑(即高可压缩性)和大压裂水平裂缝可能会使初始产油量减少13%,15年累计产油量减少10%。相反,水平裂缝扩展导致垂直水力裂缝更短、更窄。因此,垂直水力裂缝导流能力的降低预示着初始产油量可能会下降77%。最后,我们表明垂直和平面水力裂缝的几何形状并不总是一个准确的假设。在页岩储层模拟研究中,这种假设可能会导致对油气产量的高估。我们独特的储层模拟表明,在世界范围内的几个泥岩区,大量的增产工作和意想不到的低油气产量是合理的。因此,我们证明大规模压裂并不总是泥岩区成功的开发方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Impact of Horizontal Bedding Plane Fractures on Reservoir Fluid Production in Shale Oil Plays with High Pore Pressure
Massive hydraulic fracturing stimulation generates complex induced fracture systems in shale reservoirs. The complexity increases in mudrock plays characterized by overpressure and associated small differential stresses. Such conditions favor interactions between induced vertical hydraulic fractures and mechanically weak bedding planes. When these planes delaminate easily, they may hydraulically stimulate large horizontal fracture components. In such situations, weak bedding planes are critical during hydraulic fracture propagation, impacting the fracture geometry and associated hydrocarbon production. We examine the effect of stimulated mechanically weak horizontal bedding planes on reservoir fluid production in multilayered mudrock plays distinguished by high pore pressure. We propose two idealized but viable geometries (‘fracture scenarios’) reported to occur in some overpressured shale plays. Our reference scenario comprises only vertical and planar hydraulically induced fractures. In the second geometry, we add stimulated horizontal bedding plane fractures that intersect the vertical hydraulic fractures. Next, we integrate the predetermined fracture geometries into a commercial reservoir simulator (CMG-IMEX) and assess the wellbore flow performance. Finally, we perform sensitivity analyses on horizontal fracture closure-mechanism, position and number of horizontal fractures, and reduced vertical fracture permeability. The results reveal that large horizontal fractures compromise hydrocarbon production. We conclude that horizontal fracture compressibility and vertical hydraulic fracture permeability are critical parameters during reservoir simulation. Compared with the reference scenario, the unpropped (i.e., highly compressible) and large stimulated horizontal fractures may reduce the initial oil production by 13% and the cumulative oil production at 15 years by 10%, assuming the highly conductive vertical hydraulic fractures. In contrast, horizontal fracture propagation results in shorter and narrower vertical hydraulic fractures. Thus, the lowered vertical hydraulic fracture conductivity predicts that initial oil production may decline by up to 77%. Finally, we show that vertical and planar hydraulic fractures geometry is not always an accurate assumption. This assumption may lead to an overestimation of hydrocarbon production during shale reservoir simulation studies. Our unique reservoir simulations show a numerical justification for the massive stimulation jobs and the unexpectedly low hydrocarbon production obtained in several mudrock plays worldwide. Consequently, we demonstrate that massive fracturing treatments may not always be a successful development method in mudrock plays.
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