数字子卷:计算方法和渗透率-孔隙度转换

J. Li, S. R. Hussaini, H. Al-Mukainah, J. Dvorkin
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引用次数: 0

摘要

采用栅格-玻尔兹曼(LB)单相流体流动模拟方法,计算了大型数字样品(粗风沙的分段三维微ct扫描图像)的总孔隙度和绝对渗透率。另一种更快的方法是将大样本分成子卷(元素),并对每个元素使用LB方法。然后,通过Darcy对由元素渗透率组成的合成体积进行模拟,获得了宿主样品的渗透率。在本例中,第一种方法和第二种方法的结果实际上是相同的。使用子体也有助于从单个数字对象中产生物理上有意义的渗透率-孔隙度趋势。这些结果可能仅在具有良好连接和均匀孔隙空间的样品中有效。一个反例来自碳酸盐,其中相当一部分孔隙体积位于孔洞中。在这里,大多数亚样品形成的渗透率-孔隙度趋势超过了宿主样品的渗透率约半个数量级,这是由于将宿主划分在孤立的洞穴中时增强了连通性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Digital Subvolumes: Computational Approaches and Permeability-Porosity Transforms
Summary The total porosity and absolute permeability of a large digital sample, a segmented 3D micro-CT-scan image of coarse aeolian sand, is computed using the Lattice-Boltzmann (LB) single-phase fluid flow simulation. An alternative and faster approach is to divide the large sample into subvolumes (elements), and use the LB method on each element. The permeability of the host sample is then obtained by Darcy's simulation on a synthetic volume comprised of the elemental permeabilities. The results of the first and the second method are practically identical in this example. Using subvolumes also helps produce a physically meaningful permeability-porosity trend from a single digital object. These results are likely to be valid only in samples with well-connected and homogeneous pore space. A counterexample comes from carbonate where appreciable part of the pore volume is located in vugs. Here the permeability-porosity trend formed by the majority of the subsamples exceeds the permeability of the host sample by about half of an order of magnitude due to the enhanced connectivity when dividing the host across the isolated vugs.
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