The influence of gas injection and production rates on pore-scale gas-water movement in low-permeability heterogeneous gas storage based on microfluidic technique

Abstract

This study investigated the impact mechanism of gas injection and production rates on the gas-water movement behaviors at the pore-scale in low-permeability heterogeneous gas storages. To achieve this, a series of microfluidics experiments was conducted using large-scale chips under different injection and production rate conditions. The dynamic evolution of gas-water distributions, migration pathways, and gas-bearing pore spaces was recorded and quantitatively analyzed. The results indicate that slow injection combined with fast production significantly improved the utilization efficiency of gas-bearing pore spaces. Slow injection promoted more uniform gas displacement and reduced fingering, while the fast production suppressed water occupation in pore throats and mitigated water-locking effects. Conversely, fast injection and slow production led to rapid early gas invasion but increased the formation of water-locked capillary valves, resulted in a higher proportion of bound pore-throats and reduced effective gas storage spaces during subsequent rounds. Microscopic observations showed that repeated injection–production processes progressively increase water-locked throats, limiting further gas migration. Parameter analysis based on capillary number demonstrated that the slow injection/fast production strategies favored the expansion of dynamic gas-bearing boundaries and lowered bound-throat ratios. Furthermore, pore-scale transport mechanisms are discussed using single pore-throat models, highlighted the roles of wettability, corner flow, and capillary resistance in controlling gas advance and retreat behaviors. The findings providing valuable insights into optimizing injection-production strategies for low-permeability heterogeneous gas storages, and offering theoretical support for improving gas storage efficiency and reducing water-locking effects.