The Feasibility Appraisal for CO2 Enhanced Gas Recovery of Tight Gas Reservoir: Experimental Investigation and Numerical Model

Resumen

This paper proves the soundness of supercritical CO₂ displacement for enhancing gas recovery of a tight gas reservoir via laboratory investigations and compositional modeling. First, a novel phase behavior experimental device with a screened supercritical CO₂ dyeing agent were first presented to better understand the mixture characteristics between supercritical CO₂ and natural gas. The mass transfer between two vapor phases was also measured. Then, based on experimental results, the compositional model considering the influence of CO₂ diffusion on the gas recovery and critical property adjustment of supercritical CO₂ was established. The miscibility process and mixing properties, such as density, viscosity, and the flowing velocity vector, of supercriticalCO₂ and natural gas were visualized through a 3D display, which obtained a better understanding of the flooding mechanism of Enhanced Gas Recovery (EGR) via supercritical CO₂. Finally, with experiments and numerical simulations, the main benefits of CO₂ EGR were shown, which were partial miscibility between CO₂ and natural gas, pressure maintenance, and CO₂ displacement as a “gas cushion.” In general, experiments and numerical simulations demonstrate that CO₂ EGR can be seen as a promising way of prolonging the productive life and enhancing recovery of tight gas reservoirs.