期刊
GEOENERGY SCIENCE AND ENGINEERING
卷 221, 期 -, 页码 -出版社
ELSEVIER
DOI: 10.1016/j.geoen.2022.211357
关键词
Absolute permeability; Porous media; Digital rock physics; Lattice Boltzmann method; Synthetic structure; Boundary condition
Digital rock physics is recognized as a satisfactory solution for studying fluid dynamics in porous structures, and the lattice Boltzmann method performs well in this field. However, choosing the suitable boundary condition is challenging. This study aims to investigate the performance of different boundary conditions in predicting permeability of synthetic and natural structures. The results show good agreement between different boundary conditions and analytical data, recommending the use of periodic and constant pressure boundary conditions for their lower rate of change.
Digital rock physics is now recognized as a satisfactory solution for studying fluid dynamics phenomena within porous structures. On the other hand, the lattice Boltzmann method shown its capabilities in this field well. However, choosing the suitable boundary condition with the most negligible effect on flow behavior is a chal-lenge. Therefore, this study aims to introduce the most common boundary conditions, such as periodic, constant pressure, and periodic-pressure, so it focuses on investigating their performance in predicting the permeability of synthetic and natural structures. Hence, three benchmark tests are initially considered to validate the model. First, the Poiseuille flow test has been addressed, so the observations reveal that the results are in close agree-ment with the analytical solution. In the following, synthetic models are introduced as square and hexagonal arrangements. The details have shown that using different boundary conditions in permeability prediction is associated with a good agreement between the results and the analytical data. Finally, the digital image obtained by x-ray tomography of a real porous sample has been studied. Also, the sensitivity analysis for permeability estimation has been done on pressure gradient and relaxation time. Detailed investigations show that the in-crease in pressure gradient under the pressure-periodic boundary condition is associated with an increase in permeability, but it has practically no effect on the result of the periodic boundary condition. In contrast, increasing this parameter under constant pressure did not affect the permeability curve, though it grows slightly with further increase, which is quite reliable considering the compressibility error and non-Darcy flow. On the other hand, increasing the relaxation time has resulted in increased permeability. However, it is recommended to use periodic and constant pressure boundary conditions because of the lower rate of change.
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