Abstract

Diffusion is an important mass transfer mode of tight sandstone gas. Since nano-pores are extensively developed in the interior of tight sandstone, a considerable body of research indicates that the type of diffusion is mainly molecular diffusion based on Fick’s law. However, accurate modeling and understanding the physics of gas transport phenomena in nano-porous media is still a challenge for researchers and traditional investigation (analytical and experimental methods) have many limitations in studying the generic behavior. In this paper, we used Nano-CT to observe the pore structures of samples of the tight sandstone of western of Sichuan. Combined with advanced image processing technology, three-dimensional distributions of the nanometer-sized pores were reconstructed and a tight sandstone digital core model was built, as well the pore structure parameters were analyzed quantitatively. Based on the digital core model, the diffusion process of methane molecules from a higher concentration area to a lower concentration area was simulated by a finite volume method. Finally, the reservoir’s concentration evolution was visualized and the intrinsic molecular diffusivity tensor which reflects the diffusion capabilities of this rock was calculated. Through comparisons, we found that our calculated result was in good agreement with other empirical results. This study provides a new research method for tight sandstone digital rock physics. It is a foundation for future tight sandstone gas percolation theory and numerical simulation research.

Highlights

  • Tight sandstone gas (TSG) generated in tight reservoirs is one of three major types of unconventional energy

  • Based on the digital core model, the diffusion process of methane molecules from a higher concentration area to a lower concentration area was simulated by a finite volume method

  • Studies (Schloemer and Krooss 2004) have demonstrated that natural gas diffuses under the action of a concentration field and percolates under the action of a pressure field among tight matrix pores and throats, and that natural gas is released from micro- and nano-pores through three major procedures: desorption, diffusion, and percolation

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Summary

Introduction

Tight sandstone gas (TSG) generated in tight reservoirs is one of three major types of unconventional energy. A refined digital model of the pore structure of tight sandstone reservoirs was built using advanced digital core technology (Guo et al 2016; Chen et al 2015; Liu et al 2014, 2017; Ni et al 2017; Yin et al 2016), and a numerical simulation of molecular diffusion was conducted on the basis of the model. This has provided new ideas for the study of the micro-mechanisms of molecular diffusion of tight gas

Nano-CT experiment
Image processing
Fick’s first law: definition of molecular diffusion
Fick’s second law
Volume averaged form of Fick’s law
Boundary conditions
The result of molecular diffusivity simulation
Comparison results
Conclusions

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