Abstract
Low-permeability porous medium usually has asymmetric distributions of pore sizes and pore-throat tortuosity, thus has a non-linear flow behavior with an initial pressure gradient observed in experiments. A threshold pressure gradient (TPG) has been proposed as a crucial parameter to describe this non-linear flow behavior. However, the determination of this TPG is still unclear. This study provides multi-scale insights on the TPG in low-permeability porous media. First, a semi-empirical formula of TPG was proposed based on a macroscopic relationship with permeability, water saturation, and pore pressure, and verified by three sets of experimental data. Second, a fractal model of capillary tubes was developed to link this TPG formula with structural parameters of porous media (pore-size distribution fractal dimension and tortuosity fractal dimension), residual water saturation, and capillary pressure. The effect of pore structure complexity on the TPG is explicitly derived. It is found that the effects of water saturation and pore pressure on the TPG follow an exponential function and the TPG is a linear function of yield stress. These effects are also spatially asymmetric. Complex pore structures significantly affect the TPG only in the range of low porosity, but water saturation and yield stress have effects on a wider range of porosity. These results are meaningful to the understanding of non-linear flow mechanism in low-permeability reservoirs.
Highlights
Shale gas reservoirs have received increasing attention due to the depletion of conventional oil and gas resources [1]
This study aimed to develop a reliable semi-empirical formula for the threshold pressure gradient (TPG) in a numerical model of non-Darcy flow that can be used to provide a better understanding of flow mechanism in porous media with complex pore structures
A novel fractal model was developed to explore the microscopic pore structure based on this TPG formula
Summary
Shale gas reservoirs have received increasing attention due to the depletion of conventional oil and gas resources [1]. Due to the low permeability, high water saturation, and complex pore structure of shale gas reservoirs, the gas flow in a low-pressure gradient zone is always slow and non-Darcy [3,4,5,6]. The effect of diameter ratio at different branching lengths on the TPG was investigated, this fractal model could not describe the flow non-linearity induced by the existence of water saturation. This study aimed to develop a reliable semi-empirical formula for the TPG in a numerical model of non-Darcy flow that can be used to provide a better understanding of flow mechanism in porous media with complex pore structures.
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