Permeability Modeling of Pore Shapes, Compaction, Sorption, and Molecular Diffusivity in Unconventional Reservoirs

SPE Journal Pub Date : 2024-02-01 DOI:10.2118/219460-pa
Clement Afagwu, Saad Alafnan, Mohamed Mahmoud, Shabeeb Alajmei, S. Patil
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Abstract

Shale and ultratight gas reservoirs are multiscale, containing organic matter (OM) and inorganic minerals in multiple pore compartments of different pore shapes and scales. Selecting a suitable model to describe the multiscale transport mechanisms requires a minimum understanding of the inherent pore shape, OM content, typical pore size, and inherent flow regime. Interestingly, during gas production and associated pressure depletion, some mechanisms, such as pore compressibility, pore diffusion, and diffusion of sorbed gas molecules, become significant at lower pressure. In this study, multiscale and multiphysics permeability models are introduced that couple the effects of poroelasticity (especially in slit-shaped pores with <1.0 aspect ratio) and sorbed gas diffusion, Fick diffusion, transition diffusion, or Knudsen diffusion, depending on the pore structural properties at multiscale for shale and ultratight gas applications. Shale here refers to organic-rich low-permeability rock with >1–2 wt% OM, while ultratight gas has negligible organic content with <1.0 wt%. These experimentally and computationally validated models could be combined with Gaussian pressure transient solutions to effectively understand the uncertainty in multiphysics gas permeability in addition to the hydraulic and natural fracture parameters for large-scale flow simulation of hydraulically fractured unconventional reservoirs.
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非常规储层中孔隙形状、压实、吸附和分子扩散的渗透率模型
页岩和超深层气藏是多尺度的,在不同孔隙形状和尺度的多个孔隙中含有有机物(OM)和无机矿物。选择一个合适的模型来描述多尺度传输机制,需要对固有孔隙形状、OM 含量、典型孔隙尺寸和固有流动机制有最基本的了解。有趣的是,在天然气生产和相关的压力耗竭过程中,一些机制,如孔隙可压缩性、孔隙扩散和吸附气体分子的扩散,在压力较低时变得非常重要。本研究引入了多尺度和多物理场渗透率模型,将孔隙弹性的影响(尤其是在有机质含量为 1-2 wt% 的狭缝形孔隙中,而超密气体的有机质含量小于 1.0 wt%,可以忽略不计)结合起来。这些经过实验和计算验证的模型可与高斯压力瞬态解相结合,以有效了解多物理场气体渗透率的不确定性,以及水力和天然裂缝参数,用于水力压裂非常规储层的大规模流动模拟。
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