利用图论提升具有动态孔隙结构的介质的孔隙-达西尺度渗透率

IF 2.6 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Applied Computing and Geosciences Pub Date : 2024-07-17 DOI:10.1016/j.acags.2024.100179
Achyut Mishra , Lin Ma , Sushma C. Reddy , Januka Attanayake , Ralf R. Haese
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引用次数: 0

摘要

对于需要模拟流体流动的科学应用来说,渗透性是一种重要的岩石性质。虽然渗透率是通过岩芯水浸实验确定的,但最近在微计算机断层扫描成像和孔隙尺度流体流动模拟方面取得的进展,使得根据孔隙尺度的岩石结构约束渗透率成为可能。以往的研究表明,孔隙与固体颗粒的复杂关联往往会导致优先流动路径,从而影响所产生的速度场,进而影响放大的渗透率值。此外,孔隙结构可能会因微生物生长、矿物沉淀和溶解等地球化学过程而发生变化。这可能导致流场在空间和时间上的动态演变。要确定这种动态变化系统的达西渗透率,需要进行大量实验或全面的物理模拟。本研究提出了一种基于图论的方法,针对不断变化的孔隙结构,将渗透率从孔隙放大到达西尺度。该方法包括将给定的 micro-CT 岩石图像转换为图网络图,然后使用 Dijkstra 算法确定入口和出口面之间的最小阻力路径,其中阻力被量化为孔隙大小的函数。最小阻力路径相当于域内阻力最小的路径。该方法在 Sherwood 砂岩、Ketton 石灰岩和 Estaillades 石灰岩样本的显微 CT 图像上进行了测试。利用这三幅显微 CT 图像生成了 30 个地球化学诱导孔隙结构变化的合成方案,涵盖了孔隙和固体晶粒生长的范围。据观察,通过 Dijkstra 算法获得的最小阻力值与通过全物理模拟确定的放大渗透率值相关,同时将计算效率提高了 250 倍。这为使用图论方法代替全物理模拟来确定具有变化孔隙结构的样品的有效渗透率提供了信心。
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Pore-to-Darcy scale permeability upscaling for media with dynamic pore structure using graph theory

Permeability is a key rock property important for scientific applications that require simulation of fluid flow. Although permeability is determined using core flooding experiments, recent advancements in micro-CT imaging and pore scale fluid flow simulations have made it possible to constrain permeability honoring pore scale rock structure. Previous studies have reported that complex association of pores and solid grains often results in preferential flow paths which influence the resulting velocity field and, hence, the upscaled permeability value. Additionally, the pore structure may change due to geochemical processes such as microbial growth, mineral precipitation and dissolution. This could result in a flow field which dynamically evolves spatially and temporally. It would require numerous experiments or full physics simulations to determine the resultant upscaled Darcy permeability for such dynamically changing systems. This study presents a graph theory-based approach to upscale permeability from pore-to-Darcy scale for changing pore structure. The method involves transforming a given micro-CT rock image to a graph network map followed by the identification of the least resistance path between the inlet and the outlet faces using Dijkstra's algorithm where resistance is quantified as a function of pore sizes. The least resistance path is equivalent to the path of lowest resistance within the domain. The method was tested on micro-CT images of the samples of Sherwood Sandstone, Ketton Limestone and Estaillades Limestone. The three micro-CT images were used to generate 30 synthetic scenarios for geochemically induced pore structure changes covering a range of pore and solid grain growth. The least resistance value obtained from Dijkstra's algorithm was observed to correlate with upscaled permeability value determined from full physics simulations, while improving computational efficiency by a factor of 250. This provides confidence in using graph theory method as a proxy for full physics simulations for determining effective permeability for samples with changing pore structure.

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来源期刊
Applied Computing and Geosciences
Applied Computing and Geosciences Computer Science-General Computer Science
CiteScore
5.50
自引率
0.00%
发文量
23
审稿时长
5 weeks
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