用于模拟具有复杂断裂网络的页岩油藏分子扩散的新型多相多组分模型

Yi Han, Zhengdong Lei, Chao Wang, Yishan Liu, Jie Liu, Pengfei Du, Yanwei Wang, Pengcheng Liu
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引用次数: 0

摘要

分子扩散对于具有复杂断裂网络的页岩油藏的强化采油(EOR)至关重要。了解裂缝对扩散传质的影响对于预测石油采收率和剩余油分布至关重要。裂缝和基质之间的扩散传质对于全面有效地模拟分子扩散至关重要。基质单元的分辨率对裂缝-基质界面的扩散精度有很大影响。分辨率低会导致同一基质单元中出现多条裂缝,从而降低传统方法计算传质的精度。为解决这一问题,提出了一种新型多相多组分模型。新模型综合考虑了断裂间距,修改了嵌入式离散断裂模型中断裂与基质之间的分子扩散透射率。离散化采用了有限体积法中的两点通量近似。验证将较粗网格与最细网格作为可靠参考进行比较。结果表明,所提出的模型能准确捕捉到较粗网格中的扩散传质。修改后的模型研究了分子扩散对具有复杂断裂网络的页岩油藏通过二氧化碳喷射进行采收的影响。结果表明,在孔隙度和渗透率极低的情况下,提高注入率并不能提高石油采收率。分子扩散有助于二氧化碳渗透到地层中。这扩大了二氧化碳的扫描体积,增加了体积膨胀和地层能量。此外,原油中的轻质和重质成分会扩散到裂缝中并最终被生产出来,这就减少了扩散情况下的产气量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A novel multiphase and multicomponent model for simulating molecular diffusion in shale oil reservoirs with complex fracture networks
Molecular diffusion is critical for enhanced oil recovery (EOR) in shale oil reservoirs with complex fracture networks. Understanding the influence of fractures on diffusive mass transfer is crucial for predicting oil recovery and remaining oil distribution. Diffusive mass transfer between fractures and matrix is critical in comprehensively and effectively simulating molecular diffusion. Resolution of matrix cells significantly affects diffusion accuracy at the fracture–matrix interface. Low resolution results in multiple fractures in the same matrix cell, leading to decreased precision in calculating mass transfer by conventional methods. To address this, a novel multiphase and multicomponent model is proposed. The new model integrating the consideration of fracture spacing modifies molecular diffusion transmissibility between fracture and matrix in an embedded discrete fracture model. The discretization employs the two-point flux approximation in the finite-volume method. Validation compares the coarser mesh to the finest grid as a reliable reference. Results show the proposed model accurately captures diffusive mass transfer in a coarser mesh. Modified models study molecular diffusion's effects on EOR in shale oil reservoirs with complex fracture networks by CO2 huff and puff. Results indicate that increasing injection rates cannot improve oil recovery under extremely low porosity and permeability. Molecular diffusion facilitates CO2 penetration into the formation. This expands the swept CO2 volume and increases both volume expansion and formation energy. In addition, the light and heavy components of the crude oil are diffused into the fractures and eventually produced, which reduces gas production in the case of diffusion.
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