Hydro-mechanical numerical analysis of fault reactivation due petroleum production as trigger for submarine slope stability

Tasso Silva, Igor Gomes, Tiago Miranda, Julliana Fernandes, José Barbosa, Leonardo Guimarães
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Abstract

Oil production in offshore regions involves the transportation of oil and gas in submarine pipelines, which are vulnerable to geological processes triggered by subsurface oil production like fault reactivation. The fault reactivation process can lead to phenomena that impact the seabed, like subsidence and fluid exudation, and can trigger instability of submarine slopes, which can result in environmental and economic damage. The present work addresses a coupled hydromechanical numerical modeling of a hypothetical case involving fault reactivation caused by oil reservoir production and its impact on an overlying submarine slope. The hypothetical case was simulated using a finite element model. The case involves a reservoir which is cut by a fault zone that reaches the seabed. The slope instability studied was induced by the injection and production of fluids in the reservoir. The fault zone is assumed to be a sealing region and a geomechanical and pressure field discontinuity within the reservoir. Int this work was used the Mohr-Coulomb elastoplastic model with Perzyna viscoplastic regularization to represent the behavior of the fault zone and the overlying submarine slope. Results showed that the fault reactivation, caused by the reservoir production, developed shear stress and shear plastic strain along the fault and through the submarine slope, causing horizontal and vertical displacements in the slope mass and acting as a trigger factor for slope stability. Pore pressure increase at the bottom of the slope structure correlated with the injection pressure artificially increased into the reservoir.
对石油生产引起的断层再激活作为海底斜坡稳定性触发因素的水力机械数值分析
近海地区的石油生产涉及通过海底管道运输石油和天然气,而海底管道很容易受到地下石油生产引发的地质过程(如断层再激活)的影响。断层再活化过程会导致影响海底的现象,如沉降和流体渗出,并可能引发海底斜坡失稳,从而造成环境和经济损失。本研究针对油藏生产引起的断层再活化及其对上覆海底斜坡的影响这一假想情况,进行了水力机械耦合数值建模。该假想案例采用有限元模型进行模拟。该案例涉及一个被断层带切割的油藏,该断层带一直延伸到海底。所研究的斜坡不稳定性是由储油层中的液体注入和生产引起的。假定断层带是一个密封区域,也是储油层内地质力学和压力场的不连续性。在这项工作中,使用了带有 Perzyna 粘塑性正则化的 Mohr-Coulomb 弹性模型来表示断层带和上覆海底斜坡的行为。结果表明,储油层生产引起的断层重新激活,沿断层并通过海底斜坡产生了剪应力和剪切塑性应变,造成斜坡体的水平和垂直位移,成为斜坡稳定的触发因素。斜坡结构底部孔隙压力的增加与人为增加的储层注入压力有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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