分层和渗透摩擦界面对非常规储层水力压裂的影响

IF 16.4 1区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Q. Gao, A. Ghassemi
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引用次数: 2

摘要

地层分层对水力裂缝控制和泵送能量的影响是成功增产处理的关键因素。通常认为,地应力是控制裂缝高度的主要因素。力学性能对断裂高度增长的影响通常被忽视,或者仅限于考虑不同的杨氏模量。此外,通常假设不同层之间的界面是完全有界的,没有滑动,并且没有考虑界面渗透率。现场实验表明,仅凭模量和现场应力的变化并不能解释现场观察到的水力裂缝的控制(Warpinski等人,1998)。层状岩石中的韧性增强、原位应力、界面滑移和能量耗散应结合起来,有助于裂缝控制分析。在本研究中,我们在基于有限元方法开发的全耦合三维水力压裂模拟器中考虑了这些因素。我们使用实验室和数值模拟来研究这些因素,以及它们如何影响水力裂缝的扩展、高度增长和注入压力。三维全耦合流体力学模型使用特殊的零厚度界面单元和粘性区模型(CZM)来模拟裂缝扩展、界面滑移和裂缝中的流体流动。考虑了沿界面摩擦滑动的非线性力学行为。流体力学模型已通过基准分析解决方案成功验证。分析了层状杨氏模量对层状地层裂缝高度增长的影响。通过使用流体力学界面单元,明确地模拟了不同层之间的地层界面。研究了地层界面的力学和水力特性对水力裂缝扩展的影响。水力裂缝往往在杨氏模量较低的层中传播,因此软层可能会成为限制水力裂缝高度增长的屏障。与传统观点相反,水力压裂的位置(较软层与较硬层)确实会影响裂缝几何形状的演变。此外,根据界面的机械性能和导电性,沿地层界面的剪切滑移和/或开口可能导致沿界面表面的流动并终止裂缝生长。沿界面的摩擦滑移可以作为控制层状地层水力裂缝的有效机制。研究表明,水力裂缝是否会穿过不连续面,不仅取决于层的力学特性,还取决于不连续面的水力特性;沿着水平地层界面的摩擦滑移和流体压力都有助于从沿着界面的预先存在的缺陷重新引发水力裂缝,产生从拦截点到重新引发点的偏移。
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 Layering and Permeable Frictional Interfaces on Hydraulic Fracturing in Unconventional Reservoirs
The impacts of formation layering on hydraulic fracture containment and on pumping energy are critical factors in a successful stimulation treatment. Conventionally, it is considered that the in-situ stress is the dominant factor controlling the fracture height. The influence of mechanical properties on fracture height growth is often ignored or is limited to consideration of different Young’s moduli. Also, it is commonly assumed that the interfaces between different layers are perfectly bounded without slippage, and interface permeability is not considered. In-situ experiments have demonstrated that variation of modulus and in-situ stress alone cannot explain the containment of hydraulic fractures observed in the field (Warpinski et al. 1998). Enhanced toughness, in-situ stress, interface slip, and energy dissipation in the layered rocks should be combined to contribute to the fracture containment analysis. In this study, we consider these factors in a fully coupled 3D hydraulic fracture simulator developed based on the finite element method. We use laboratory and numerical simulations to investigate these factors and how they affect hydraulic fracture propagation, height growth, and injection pressure. The 3D fully coupled hydromechanical model uses a special zero-thickness interface element and the cohesive zone model (CZM) to simulate fracture propagation, interface slippage, and fluid flow in fractures. The nonlinear mechanical behavior of frictional sliding along interface surfaces is considered. The hydromechanical model has been verified successfully through benchmarked analytical solutions. The influence of layered Young’s modulus on fracture height growth in layered formations is analyzed. The formation interfaces between different layers are simulated explicitly through the use of the hydromechanical interface element. The impacts of mechanical and hydraulic properties of the formation interfaces on hydraulic fracture propagation are studied. Hydraulic fractures tend to propagate in the layer with lower Young’s modulus so that soft layers could potentially act as barriers to limit the height growth of hydraulic fractures. Contrary to the conventional view, the location of hydraulic fracturing (in softer vs. stiffer layers) does affect fracture geometry evolution. In addition, depending on the mechanical properties and the conductivity of the interfaces, the shear slippage and/or opening along the formation interfaces could result in flow along the interface surfaces and terminate the fracture growth. The frictional slippage along the interfaces can serve as an effective mechanism of containment of hydraulic fractures in layered formations. It is suggested that whether a hydraulic fracture would cross a discontinuity depends not only on the layers’ mechanical properties but also on the hydraulic properties of the discontinuity; both the frictional slippage and fluid pressure along horizontal formation interfaces contribute to the reinitiation of a hydraulic fracture from a pre-existing flaw along the interfaces, producing an offset from the interception point to the reinitiation point.
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来源期刊
Accounts of Chemical Research
Accounts of Chemical Research 化学-化学综合
CiteScore
31.40
自引率
1.10%
发文量
312
审稿时长
2 months
期刊介绍: Accounts of Chemical Research presents short, concise and critical articles offering easy-to-read overviews of basic research and applications in all areas of chemistry and biochemistry. These short reviews focus on research from the author’s own laboratory and are designed to teach the reader about a research project. In addition, Accounts of Chemical Research publishes commentaries that give an informed opinion on a current research problem. Special Issues online are devoted to a single topic of unusual activity and significance. Accounts of Chemical Research replaces the traditional article abstract with an article "Conspectus." These entries synopsize the research affording the reader a closer look at the content and significance of an article. Through this provision of a more detailed description of the article contents, the Conspectus enhances the article's discoverability by search engines and the exposure for the research.
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