A Composite Framework Model for Transient Pressure Dynamics in Tight Gas Reservoirs Incorporating Stress Sensitivity

Natural gas is an eco-friendly energy source with low carbon emissions, making it attractive globally. Understanding gas reservoirs is crucial for sustainable extraction and optimizing potential. However, the complicated fluid flow and production dynamics within intricate gas reservoirs, particularl...

Full description

Saved in:
Bibliographic Details
Published inEnergies (Basel) Vol. 16; no. 20; p. 7175
Main Authors Cao, Lina, Wang, Hehua, Jiang, Liping, Zhang, Bo, Ganzer, Leonhard, Xie, Yachen, Luo, Jiashun, Wang, Xiaochao
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.10.2023
Subjects
Analysis
Boundary conditions
Coalbed methane
Fractured reservoirs
horizontal well
Hydraulic fracturing
Investigations
Mathematical models
Natural gas
Oil wells
Permeability
Productivity
Storage
stress-sensitivity
tight gas reservoirs
transient pressure dynamics
China
Malaysia
Online AccessGet full text

Cover

More Information
Summary:Natural gas is an eco-friendly energy source with low carbon emissions, making it attractive globally. Understanding gas reservoirs is crucial for sustainable extraction and optimizing potential. However, the complicated fluid flow and production dynamics within intricate gas reservoirs, particularly those characterized by abnormally high pressures and tight porous media, remain partially understood and demand further investigation. In a tight porous medium subjected to high pressure, the assumption of constant permeability is no longer valid. Consequently, a novel composite seepage model has been developed in this study, which considers the responsiveness of permeability to stress. Perturbation theory is employed to address the inherent non-linearity demonstrated by the permeability modulus. The solution of dimensionless pressure responses under constant production conditions is accomplished in the Laplace domain by implementing integral transformation methods. Overall, a comprehensive model is provided to understand the production behaviors of tight gas reservoirs. Moreover, in order to comprehend the transient flow characteristics of tight gas reservoirs, log–log plots are generated through the Stehfest numerical inversion approach, with the flow regimes categorized based on the normalized time phases of the pressure curves. Parametric investigations reveal that stress sensitivity detrimentally affects permeability, resulting in more pronounced pressure declines during the intermediate and late flow phases. The transient seepage model elaborated in this study is able to consider the pertinent formation and well parameters. These interpreted parameters bear significance in designing hydraulic fracturing operations, assessing the potential of tight gas reservoirs, and ultimately enhancing gas production. The presented model not only enhances our understanding of the behavior of horizontal wells in stress-sensitive tight gas reservoirs but also makes a valuable contribution to the broader discussion on transient flow phenomena in petroleum engineering.
ISSN:1996-1073
1996-1073
DOI:10.3390/en16207175