Temporal and Spatial Anomalous Diffusion Flow Mechanisms in Structurally Complex Porous Media: The Impact on Pressure behavior, Flow regimes, and Productivity Index

S. Al-Rbeawi
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引用次数: 1

Abstract

The main objective of this paper is understanding the phenomenal anomalous diffusion flow mechanisms in unconventional fractured porous media. This understanding is crucial for estimating the impact of these flow mechanisms on pressure behavior, flow regimes, and transient and pseudo-steady state productivity index of the two cases of inner wellbore conditions: constant sandface flow rate and constant wellbore pressure. The targets are hydraulically fractured unconventional reservoirs characterized by porous media with complex structures. These media are consisted of a matrix and naturally induces fractures embedded in the matrix as well as hydraulic fractures. Several analytical models for pressure drop and decline rate as wells productivity index in ultralow permeability reservoirs are presented in this study for the two inner wellbore conditions. A numerical solution is also presented in this study for pressure behavior using a linearized implicit finite difference method. The analytical models are developed from trilinear flow models presented in the literature with a consideration given to the temporal and spatial fractional pressure derivative for the ano malous diffusion flow that could be the dominant flow mechanism in the stimulated reservoir volume between hydraulic fractures. Mittag-Leffler functions are used for solving fractional derivatives of pressure and flow rate considering that temporal and spatial fractional exponents are less than one. Two solutions are developed in this study for the two inner wellbore conditions. The first represents the transient state condition that controls fluid flow in unconventional reservoirs for very long produc tion time. The second is the solution of pseudo-steady state condition that might be observed after transient state flow. The second solution is used for estimating stabilized pseudo-steady state productivity index considering different reservoir conditions. In the numerical solution, the temporal and spatial domains are discretized into several time steps and block-centered grids respectively. The results of the analytical models are compared with numerical solutions. The outcomes of this study are: 1) Understanding the impact of temporal and spatial diffusion flow mechanisms on pressure behavior, flow rate declining pattern, and productivity index scheme during early and late production time. 2) Developing analytical and numerical models for fractional derivatives of pressure and flow rate considering diffusion flow mechanisms 3) Developing analytical models for different flow regimes that could be developed during the entire production life of reservoirs. 4) Studying the impact of reservoir configuration and wellbore type as well as different temporal and spatial diffusion flow conditions on stabilized pseudo-steady state productivity index. The study has pointed out: 1) Temporal and spatial diffusion flow have a significant impact on pressure drop, flow rate, and productivity index. 2) Wellbore pressure drop for constant Sandface flow rate declines rapidly as the temporal diffusion flow mechanism is the dominant flow pattern in the porous media. 3) Wellbore pressure drop for constant Sandface flow rate slightly increases during transient state flow as the spatial diffusion flow mechanisms increase and rapidly increases during pseudo-steady state flow. 4) Productivity index of diffusion flow is higher than the index of normal diffusion flow during transient and pseudo-steady state conditions. 5) The linear flow regime is most affected by anomalous diffusing flow and can be used to characterize the type of diffusion flow.
结构复杂多孔介质中的时空异常扩散流动机制:对压力行为、流动状态和产能指数的影响
本文的主要目的是了解非常规裂缝性多孔介质中现象异常扩散流动机制。这种理解对于评估这些流动机制对压力行为、流动状态以及两种井内条件下的瞬态和准稳态产能指数的影响至关重要:恒定的砂面流速和恒定的井筒压力。目标层为以孔隙介质、结构复杂为特征的水力压裂非常规储层。这些介质由基质组成,自然诱发嵌入基质中的裂缝以及水力裂缝。针对这两种井内条件,提出了几种超低渗透油藏压降和递减率作为井产能指标的分析模型。本文还提出了用线性化隐式有限差分法求解压力特性的数值解。分析模型是在文献中提出的三线性流动模型的基础上发展起来的,考虑了非稳态扩散流动的时间和空间分数压力导数,这可能是水力裂缝之间的压裂油藏体积的主要流动机制。考虑到时间和空间分数阶指数均小于1,采用mittagi - leffler函数求解压力和流量的分数阶导数。针对两种井内情况,本研究提出了两种解决方案。第一个代表了在很长生产时间内控制非常规油藏流体流动的瞬态条件。二是暂态流动后可能观察到的拟稳态条件的求解。第二种解用于估计考虑不同储层条件的稳定拟稳态产能指数。在数值解中,将时域和空域分别离散为几个时间步长和块中心网格。将解析模型的结果与数值解进行了比较。研究结果如下:1)了解了时空扩散流动机制对生产前期和后期压力行为、流量下降规律和产能指标方案的影响;2)建立考虑扩散渗流机制的压力和流量分数导数的解析和数值模型;3)建立油藏全生产周期内不同流态的解析模型。4)研究储层构型、井眼类型以及不同时空扩散流动条件对稳定拟稳态产能指标的影响。研究指出:1)时空扩散流对压降、流量和产能指标有显著影响。2)当砂面流速不变时,由于多孔介质中以时间扩散渗流机制为主,井筒压降迅速下降。3)恒定流速下瞬态流动时井筒压降随着空间扩散流动机制的增加而略有增加,拟稳态流动时井筒压降迅速增加。4)在瞬态和拟稳态条件下,扩散流的生产率指数高于正常扩散流的生产率指数。5)线性流型受异常扩散流的影响最大,可以用来表征扩散流的类型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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