Simulation Study of Nanoparticle Transport in Porous Media: Effects of Salinity and Reservoir Parameters

S. N. Apourvari, Mehdi Rezaei Abiz, S. Jafari, M. Schaffie
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Abstract

Although experimental studies confirmed the effectiveness of nanoparticles in enhanced oil recovery applications, no comprehensive investigation has been carried out to reveal the effect of different subsurface factors on this improvement. Proper application of nanoparticles mainly depends on their ability to travel long distances within a reservoir without agglomeration, retention and blocking the pore throats. This study strengthens our understanding about the effect of the main subsurface factors on the nanofluid-assisted enhanced oil recovery. For doing so, a transport approach utilizing kinetic Langmuir model is developed and validated using experimental data. Thereafter, the effect of reservoir rock type and its properties (clay content and grain size), salinity of injected fluid, and reservoir temperature on the transport and retention of nanoparticles in porous media in relation to enhanced oil recovery methods is investigated. Since the amount of nanoparticles in the injected fluid and on the rock surface (as deposited) control the mobility and wettability alteration, the effect of subsurface factors and salinity of injected fluid on this deposition is also analyzed. The results showed that the rock type and its properties significantly affect the transport and retention of nanoparticles in porous media. It was also found that the brine salinity has the greatest impact on the amount of nanoparticles deposited on the rock surface. The surface covered by NPs increased from 10 to 82 % after changing salinity from 3 weight percent NaCl to API brine.
多孔介质中纳米颗粒输运的模拟研究:盐度和储层参数的影响
虽然实验研究证实了纳米颗粒在提高采收率方面的有效性,但目前还没有开展全面的研究来揭示不同地下因素对这种改善的影响。纳米颗粒的正确应用主要取决于它们在储层内长距离移动的能力,而不会聚集、滞留和堵塞孔喉。该研究加深了我们对纳米流体辅助提高采收率的主要地下因素影响的认识。为此,提出了一种利用动力学Langmuir模型的输运方法,并用实验数据进行了验证。随后,研究了储层岩石类型及其性质(粘土含量和粒度)、注入流体矿化度和储层温度对纳米颗粒在多孔介质中运移和滞留的影响,以及提高采收率的方法。由于注入流体和岩石表面(沉积)纳米颗粒的数量控制着流动性和润湿性的变化,因此还分析了地下因素和注入流体盐度对这种沉积的影响。结果表明,岩石类型及其性质对纳米颗粒在多孔介质中的运移和滞留有显著影响。研究还发现,盐水盐度对岩石表面纳米颗粒沉积量的影响最大。当盐浓度从3% NaCl变为API盐水后,NPs的表面覆盖率从10%增加到82%。
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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