基于粘弹性压实规律的孔隙压力预测地质模型

Roland I. Nwonodi, A. Dosunmu
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引用次数: 2

摘要

开发一种能够模拟现场孔隙压力分布的模型非常重要,特别是在超压段,主要是由于井筒不稳定、水力压裂处理、漏失、井涌和井喷造成的。目前预测孔隙压力的方法依赖于Terzaghi的总应力,但需要准确确定岩石中的有效应力。盆地中发生的沉积过程使岩石受到压实作用,这种压实作用可以是粘弹性的。预测孔隙压力的常规压实方法只考虑机械压实,但粘性压实也很重要,特别是在地下2000米以上。在这项研究中,通过将考虑粘弹性压实的有效应力定律应用于Terzaghi应力方程,建立了一个预测孔隙压力的模型。从有效应力与变形速率的关系出发,提出了总有效应力随时间的表达式。适用的边界条件是关于穿越岩石的时间。使用墨西哥湾沿岸10,000英尺井眼的传输时间数据,得到的压力梯度为0.885 psi/ft,相比之下,修正Eaton模型得到的压力梯度为0.863 psi/ft, Zhang模型得到的压力梯度为0.9132 psi/ft。30,000英尺井眼所需的另一个压力产生的压力梯度为0.535 psi/ft,而实测地层压力得到的压力梯度为0.52 psi/ft。结果表明,粘弹性压实可以准确地定义岩石的孔隙压力分布。此外,模拟结果表明,影响孔隙压力最重要的变量是覆盖层应力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Geomodel for Pore Pressure Prediction Based on A Viscoelastic Compaction Law
It is important to develop a model that simulates in situ pore pressure profile especially in an overpressured interval mainly because of wellbore instability, hydraulic fracturing treatment, lost circulation, kick, and blowout. The current methodology for predicting pore pressure depends on the Terzaghi's total stress but requires the accurate determination of the effective stress in the rock. The sedimentary processes occurring in a basin put the rock under compaction, which can be viscoelastic. The normal-compaction methods of predicting pore pressure consider only mechanical compaction, but viscous compaction is important to consider, especially beyond 2000 meters of the subsurface. In this study, a model for predicting pore pressure was developed by applying an effective stress law that considers viscoelastic compaction into the Terzaghi's stress equation. From the relationship defining effective stress and the rate of deformation, the author posed an expression for the total effective stress in terms of time. The applicable boundary condition was with respect to the transit time through the rock. Using transit time data for a Gulf Coast wellbore at 10,000 ft yielded a pressure gradient of 0.885 psi/ft, which compares to 0.863 psi/ft obtained from the modified Eaton's model and 0.9132 psi/ft obtained from the Zhang model. Another pressure required for a wellbore at 30,000 ft yielded a pressure gradient of 0.535 psi/ft, which compares with 0.52 psi/ft obtained from measured formation pressure. Thus, the results indicate that the viscoelastic compaction accurately defines the pore pressure profile in a rock. Furthermore, simulation results indicate that the most important variable affecting pore pressure is the overburden stress.
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