扩散方程渐近解在无限作用压力瞬态分析中的应用

IF 3.2 3区 工程技术 Q1 ENGINEERING, PETROLEUM
SPE Journal Pub Date : 2024-05-01 DOI:10.2118/180149-pa
Zhenzhen Wang, Chen Li, Michael J. King
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引用次数: 0

摘要

了解压力如何在储层中传播是解释油井压力和流速瞬态测量的基础。非常规储层提供了独特的技术挑战,因为在油井测试分析中应用的简单几何形状和流动机制[井筒存储(WBS)和径向、线性、球形和边界主导流动]现在已被复杂的多级压裂完井、非平面裂缝以及流动与储层异质性的相互作用所导致的非理想流动模式所取代。在本文中,我们介绍了一种适用于压力瞬态分析(PTA)的扩散方程渐近求解技术,将三维耗竭几何图形映射为等效的一维流管。与通常的解释方法相比,这种方法假定了耗竭几何形状,而地层和油井的参数则是未知属性。该构造基于艾克纳方程的解法,而艾克纳方程是从异质储层的扩散方程中推导出来的。我们开发了一个格林函数,为压力瞬态方程提供解析解,其中流动模式的几何形状从瞬态解中抽象出来。解析公式为许多油井测试压力瞬态特征(如油井测试半对数压力导数 (WTD)、勘探深度 (DOI) 和稳定区 (SZ)(或动态排水区))提供了明确的解决方案,并为可探测极限 (LOD)、瞬态排水量和伪稳态 (PSS) 极限提供了新的定义。将格林函数方法推广到有界水库是可能的(Wang 等人,2017 年),但超出了当前研究的范围。我们根据使用拉普拉斯变换求解的著名 PTA 解法验证了我们的方法,包括带有 WBS 和表皮的压力瞬态。最后,我们还讨论了非常规储层性能分析的应用,因为目前还不存在这方面的参考解决方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Applications of Asymptotic Solutions of the Diffusivity Equation to Infinite Acting Pressure Transient Analysis
Understanding how pressure propagates in a reservoir is fundamental to the interpretation of pressure and rate transient measurements at a well. Unconventional reservoirs provide unique technical challenges as the simple geometries and flow regimes [wellbore storage (WBS) and radial, linear, spherical, and boundary-dominated flow] applied in well test analysis are now replaced by nonideal flow patterns due to complex multistage fracture completions, nonplanar fractures, and the interaction of flow with the reservoir heterogeneity. In this paper, we introduce an asymptotic solution technique for the diffusivity equation applied to pressure transient analysis (PTA), in which the 3D depletion geometry is mapped to an equivalent 1D streamtube. This allows the potentially complex pressure depletion geometry within the reservoir to be treated as the primary unknown in an interpretation, compared with the usual method of interpretation in which the depletion geometry is assumed and parameters of the formation and well are the unknown properties. The construction is based upon the solution to the Eikonal equation, derived from the diffusivity equation in heterogeneous reservoirs. We develop a Green’s function that provides analytic solutions to the pressure transient equations for which the geometry of the flow pattern is abstracted from the transient solution. The analytic formulation provides an explicit solution for many well test pressure transient characteristics such as the well test semi-log pressure derivative (WTD), the depth of investigation (DOI), and the stabilized zone (SZ) (or dynamic drainage area), with new definitions for the limit of detectability (LOD), the transient drainage volume, and the pseudosteady-state (PSS) limit. Generalizations of the Green’s function approach to bounded reservoirs are possible (Wang et al. 2017) but are beyond the scope of the current study. We validate our approach against well-known PTA solutions solved using the Laplace transform, including pressure transients with WBS and skin. Our study concludes with a discussion of applications to unconventional reservoir performance analysis for which reference solutions do not otherwise exist.
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来源期刊
SPE Journal
SPE Journal 工程技术-工程:石油
CiteScore
7.20
自引率
11.10%
发文量
229
审稿时长
4.5 months
期刊介绍: Covers theories and emerging concepts spanning all aspects of engineering for oil and gas exploration and production, including reservoir characterization, multiphase flow, drilling dynamics, well architecture, gas well deliverability, numerical simulation, enhanced oil recovery, CO2 sequestration, and benchmarking and performance indicators.
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