湍流条件下HPAM提高采收率溶液力学退化的CFD模拟

J. Herrera, L. Prada, G. Maya, Jose Gómez, Ruben Castro, H. Quintero, Robinson Jimenez Diaz, Eduar Pérez
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引用次数: 3

摘要

聚合物驱是一种应用广泛的提高采收率技术。聚合物的目的是增加水的粘度,以提高储层的波及效率。然而,聚合物注射设备的机械元件可能会对聚合物的粘度产生负面影响,使其急剧降低。聚合物的机械降解发生在阀门和控制系统中突然改变直径的流动限制的情况下。这种流动限制可能引起沿聚合物链的机械应力,从而导致其断裂。在本研究中,采用物理实验和CFD(计算流体动力学)的数值模拟,提出了一个估计聚合物溶液流动力学退化的模型。该技术通过几何限制计算流速梯度、压降和流体的聚合物降解。通过聚合物注入实验验证了仿真结果。结果表明:随着体积流量的增大和有效直径的减小,聚合物剪切引起的机械降解越多;然而,这取决于每种聚合物在水溶液中固有的流变性能。该方法适用于估计聚合物溶液在驱油设施和附件中的机械降解。此外,获得的结果可以增强聚合物的使用,计算其实际机械降解,最小化它,或使用它来支持新配件的开发。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
CFD simulation of HPAM EOR solutions mechanical degradation by restrictions in turbulent flow
Polymer flooding is a widely used enhanced oil recovery (EOR) technology. The purpose of the polymer is to increase water viscosity to improve reservoir sweep efficiency. However, mechanical elements of the polymer injection facilities may impact the viscosity of the polymer negatively, decreasing it drastically. Mechanical degradation of the polymer occurs in case of flow restrictions with abrupt diameter changes in valves and control systems. Such flow restrictions may induce mechanical stresses along the polymer chain, which can result in its rupture. In this research, physical experiments and numerical simulations using CFD (Computational Fluid Dynamics) were used to propose a model for estimating the mechanical degradation for the flow of polymer solutions. This technique involves the calculation of velocity gradients, pressure drawdown, and polymer degradation of the fluid through geometry restriction. The simulations were validated through polymer injection experiments. The results show that with the greater volumetric flow and lower effective diameters, there is more mechanical degradation due to polymer shearing; nonetheless, this depends on the rheology properties inherent in each polymer in an aqueous solution. This method is suitable to estimate the mechanical degradation of the polymer solution in flooding facilities and accessories. Further, the results obtained could enhance the use of the polymer, calculating its actual mechanical degradation, minimizing it, or using it to support the development of new accessories.
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