Macroscale Gas-Water Two-Phase Transport Simulation in Shales considering Nanomicroscale Effects

As an effective approach to evaluate shale gas production, macroscale numerical simulations have been conducted; however, multiscale storage space and complex gas-water two-phase transport mechanisms are not systematically considered. To deal with this, a rigorous cross-scale gas-water two-phase transport simulation method that considers the pore, core, and field scale is proposed herein. First, to investigate the fluid storage state in different pore types during the gas-water two-phase transport process, a shale pore network gas-water transport simulation is conducted. Subsequently, a core-scale model that considers the distribution of organic matter is constructed, and the gas-water two-phase transport behaviors are upscaled from the pore to the core by incorporating nanomicroscale effects. Next, a shale gas-water two-phase macroscale numerical simulation is implemented based on the core-scale simulation results. Multiple interacting continua are used to describe the shale matrix and microfractures, whereas the embedded discrete fracture method is employed to represent hydraulic fractures. Finally, the manner by which nanomicroscale effects, stress sensitivity, and SRV area affect the production of shale gas reservoirs is discussed comprehensively. This study provides a practical method to estimate shale gas production by rigorously considering gas-water nanomicroscale effects to reduce uncertainties during productivity evaluation.