Abstract
In the development process of thick reservoirs, the impact of various geological factors on the effectiveness of the CO(2) water alternating gas (CO(2)-WAG) flooding technology remains unclear. This paper establishes multiple CO(2)-WAG flooding models for thick reservoirs to study the effects of sedimentary rhythm, dip angle, matrix permeability, high-permeability streaks (HPS), and barrier layers on the effectiveness of CO(2)-WAG flooding and then uses the random forest algorithm to rank the importance of these geological factors. The results show that different geological factors have varying degrees of impact on the distribution of water and gas migration and recovery rates during the CO(2)-WAG flooding process. The ranking of the importance of various factors obtained by reservoir numerical simulations and the random forest algorithm is HPS, sedimentary rhythm, dip angle, matrix permeability, and barrier layers. These research findings will provide effective guidance and a reference for the optimal selection of CO(2)-WAG flooding schemes for similar thick reservoirs under different geological conditions.