An accelerated process-based method for the accurate computation of relative permeability from direct simulations of two-phase flow on micro-computed tomography images of porous media

2区 工程技术 Q1 Earth and Planetary Sciences
Faruk O. Alpak, Nishank Saxena
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引用次数: 2

Abstract

Pore-scale forces have significant effects on the macroscopic behavior of multi-phase flow through porous media. We develop a robust and accurate accelerated process-based method for the computation of relative permeability from direct simulations of pore-scale two-phase flow on micro-computed tomography images. In the pressure drop calculation, we take advantage of an existing analysis that establishes a relationship between pore-scale forces and Darcy-scale pressure drops using an energy-conservation approach. We establish a thermodynamically consistent approximation of Darcy-scale viscous pressure drops as the rate of energy dissipation per unit flow rate of each flowing phase for the first time within the context of a free-energy lattice Boltzmann method (LBM). In addition, we propose and test a new computationally efficient partial-mirror periodic boundary condition for a fully coupled visco-capillary pore-scale flow simulator based on a free-energy LBM. The new boundary condition is imposed only in the main flow direction and significantly reduces the computational cost of the process-based relative-permeability computation protocol at a small compromise on accuracy.

We first compute primary-drainage and subsequent imbibition relative permeability curves for a reservoir sandstone rock sample. We use this real-reservoir dataset to validate the pressure drop computation method and the partial-mirror periodic boundary condition. We then simulate the entire drainage and imbibition cycle using an extensively studied Berea sandstone dataset. We quantitatively demonstrate that pore-scale direct numerical simulation-based relative permeability curves computed with our novel process-based method agree well with experimental steady-state relative permeability measurements. We also quantitatively demonstrate that the new partial-mirror periodic boundary condition accelerates the relative permeability computations 4 to 13 times.

基于加速过程的多孔介质微计算机断层扫描图像两相流直接模拟相对渗透率精确计算方法
孔隙尺度力对多孔介质中多相流的宏观行为有重要影响。我们开发了一种鲁棒和精确的基于加速过程的方法来计算相对渗透率,从微观计算机断层扫描图像上直接模拟孔隙尺度的两相流。在压降计算中,我们利用了现有的分析,该分析利用节能方法建立了孔隙尺度力和达西尺度压降之间的关系。在自由能晶格玻尔兹曼方法(LBM)的背景下,首次建立了达西尺度粘性压降的热力学一致近似,即每个流动相单位流速的能量耗散率。此外,我们提出并测试了一种新的计算效率高的部分镜像周期边界条件,用于基于自由能LBM的完全耦合粘-毛细孔尺度流动模拟器。新的边界条件只施加在主流方向上,在很小的精度上降低了基于过程的相对渗透率计算协议的计算成本。我们首先计算了储层砂岩样品的初次排水和随后的渗吸相对渗透率曲线。利用实际油藏数据集验证了压降计算方法和部分镜像周期边界条件。然后,我们使用广泛研究的Berea砂岩数据集模拟整个排水和渗吸循环。我们定量地证明了用我们的新方法计算的基于孔隙尺度直接数值模拟的相对渗透率曲线与实验稳态相对渗透率测量值吻合得很好。我们还定量地证明了新的部分镜像周期边界条件使相对渗透率的计算速度提高了4 ~ 13倍。
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来源期刊
Journal of Petroleum Science and Engineering
Journal of Petroleum Science and Engineering 工程技术-地球科学综合
CiteScore
11.30
自引率
0.00%
发文量
1511
审稿时长
13.5 months
期刊介绍: The objective of the Journal of Petroleum Science and Engineering is to bridge the gap between the engineering, the geology and the science of petroleum and natural gas by publishing explicitly written articles intelligible to scientists and engineers working in any field of petroleum engineering, natural gas engineering and petroleum (natural gas) geology. An attempt is made in all issues to balance the subject matter and to appeal to a broad readership. The Journal of Petroleum Science and Engineering covers the fields of petroleum (and natural gas) exploration, production and flow in its broadest possible sense. Topics include: origin and accumulation of petroleum and natural gas; petroleum geochemistry; reservoir engineering; reservoir simulation; rock mechanics; petrophysics; pore-level phenomena; well logging, testing and evaluation; mathematical modelling; enhanced oil and gas recovery; petroleum geology; compaction/diagenesis; petroleum economics; drilling and drilling fluids; thermodynamics and phase behavior; fluid mechanics; multi-phase flow in porous media; production engineering; formation evaluation; exploration methods; CO2 Sequestration in geological formations/sub-surface; management and development of unconventional resources such as heavy oil and bitumen, tight oil and liquid rich shales.
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