孔隙弹性致密油气地层流体流动时井周应力分布的数值模拟:有限元法的应用

H. Zhang, A. Shaik, M. M. Rahman
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引用次数: 0

摘要

在油气地层中,井筒周围注入的流体会影响地层的应力分布,从而改变地层的应力状态。这使得水力裂缝的扩展更加复杂。研究了不同流体流动条件下井筒周围的应力分布。采用局部耦合策略,从应力模型和流体流动模型中得到有效应力。采用有限元法计算了随流体压力变化的总应力分布和有效应力。建立了一个数值模型,并通过商业软件和解析解进行了验证。应用所建立的数值模型计算了有效应力分布。通过数值试验找出影响有效应力的因素。结果表明,该模型能够有效地捕捉井筒周围的总应力分布和有效应力分布。模型还表明,流体压力对应力分布有显著影响。数值实验结果表明,有效应力随井筒半径和岩石压缩性增大而增大,随流体注入量和岩石压缩性增大而减小。研究结果可用于改进井筒附近应力分布的模拟,用于水力压裂设计。
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Numerical Simulation of Stress Distribution Around a Well due to Fluid Flow in Poroelastic Tight oil and Gas Formation: An Application of Finite Element Method
Fluid injected around a wellbore in an oil and gas formation will affect the stress distribution which may change the stress state. This makes the hydraulic fracture more complex to propagate. Stress distribution around a wellbore is investigated in different fluid flowing conditions. The partial coupling strategy is applied to get effective stress from the stress model and fluid flow model. Finite Element Method is used to calculate the total stress distribution and the effective stress with fluid pressure. A numerical model is developed and verified by a commercial software and analytical solution. The developed numerical model is applied to generate the effective stress distribution. Numerical experiments are conducted to find out the factors to the effective stress. The results from current model suggest that it can effectively capture the total stress distribution and effective stress distribution around the wellbore. Model also suggests that fluid pressure has a significant effect on the stress distribution. The results from numerical experiments show that effective stress increases with wellbore radius and rock compressibility, but decreases with the fluid injection rate and rock compressibility. The results of this study can be used to improve the simulation of stress distribution near a wellbore for hydraulic fracturing design.
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