Oil-water relative permeability of low permeability reservoir in fractal theory
2021-12-15
SU Haibo1,2, ZHANG Shiming2, SUN Yeheng2, YU Jinbiao2, YANG Minglin2, MENG Wei2,
WANG Yong2, YU Mingli3
1. Department of Thermal Science and Energy Engineering, University of Science and Technology of China,
Hefei City 230027, Anhui Province, China;
2. Exploration and Development Research Institute, Shengli Oilfield Company, SINOPEC, Dongying City 257015,
Shandong Province, China;
3. College of Chemical Engineering, China University of Petroleum (East China), Qingdao City 266580,
Shandong Province, China
Abstract: Oil-water relative permeability is an important parameter for studying the characteristics of water flooding development in low permeability reservoirs. It is of great practical significance to understanding the percolation law in the low permeability reservoirs by determining the influencing factors of oil-water relative permeability. On the fractal theory of porous media, a mathematical model of oil-water relative permeability in the low permeability reservoirs and a normalized oil-water relative permeability model are built respectively. This model is a function of water saturation, displacement pressure, and capillary pressure, which can comprehensively reflect the influence of reservoir pore structure, nonlinear percolation, and percolation interference on oil-water relative permeability. The theoretical analysis result shows that the more complex core pore structure is, the lower oil-water relative permeability will be; the displacement pressure influences relative permeability of oil phase, which shows that there is a dynamic change of relative permeability in the process of water flooding. Nonlinear percolation has a great influence on the relative permeability of oil phase, but the influence on the relative permeability of water phase may be ignored. The relative permeability of oil phase decreases with the increase in oil nonlinear coefficient. The percolation interference influences the relative permeability of the oil and water phases which decreases with the increase in interference coefficient. The oil-water relative permeability predicted by the model is compared with the experimental results to verify the reliability of the model. The predicted oil-water relative permeability of the model is highly consistent with the experimental results. In addition, the comparison with the prediction results of the classical theoretical model of relative permeability shows that the prediction results of the new model for the relative permeability of water phase are better than those of the classical theoretical models.