Improving Polymer Flooding by Addition of Surface Modified Nanoparticles

L. M. Corredor, B. Maini, M. Husein
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引用次数: 10

Abstract

The objective of this study was to examine the feasibility of improving the performance of EOR polymers by adding surface modified silica nanoparticles (NP). The nano-polymer sols were prepared by mixing different types of surface modified silica NP and hydrolyzed polyacrylamide (HPAM) or xanthan gum (XG) solutions. It is well known that the compatibility between organic polymer-inorganic oxide filler increases when the surface of the inorganic filler is chemically modified. To generate different interfacial interactions, the silica NP were treated by chemical grafting with carboxylic acids and silanes. The properties of the modified silica NP were characterized using Fourier transform infrared spectroscopy (FTIR) and the properties of the nano-polymer sols were investigated with viscometry and ζ-potential measurements. The non-Newtonian behavior of the nano-polymer sols was represented by Oswald-de Waele model. Areal sweep efficiency of viscous oil displacements by nano-polymer sols was measured at 25°C in a Hele-Shaw cell representing one-quarter of a five-spot pattern. The fingering patterns of all XG samples were characterized by the formation of branched structures (at earlier growth stage) which by merging and coalescing formed stable interfaces. It was the expected behavior considering the high shear-thinning strength of the XG polymer and nano-polymer sols (n values between 0.17 and 0.27). However, the HPAM solutions and nano-polymer sols exhibited different fingering patterns with tip-splitting or suppressed tip-splitting and side-branching. This difference was attributed to different interactions between the modified NP and the polymeric chains of the two polymers. The areal sweep efficiency of the HPAM polymer solutions did not improve by the addition of any type of NP because of the reduction of the viscosity of the polymer solution and the reduction of the interfacial tension between the injection fluid and oil. However, the XG polymer solutions, modified with the addition of 1.0 and 2.0 wt.% NP provided considerably improved sweep efficiency. The results are promising and show good potential for improving the performance of polymer flooding with Xanthan gum by addition of silica NP.
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添加表面改性纳米颗粒改善聚合物驱油性能
本研究的目的是研究通过添加表面改性二氧化硅纳米颗粒(NP)来改善提高采收率聚合物性能的可行性。将不同类型的表面改性二氧化硅NP与水解聚丙烯酰胺(HPAM)或黄原胶(XG)溶液混合制备纳米聚合物溶胶。众所周知,对无机填料表面进行化学改性后,有机聚合物-无机氧化物填料之间的相容性提高。为了产生不同的界面相互作用,将二氧化硅NP与羧酸和硅烷进行化学接枝处理。利用傅里叶变换红外光谱(FTIR)表征了改性二氧化硅NP的性能,并用粘度法和ζ电位法研究了纳米聚合物溶胶的性能。用Oswald-de Waele模型描述了纳米聚合物溶胶的非牛顿行为。在25°C的Hele-Shaw电池中测量了纳米聚合物溶胶驱稠油的面积波及效率,代表了四分之一的五点模式。所有XG样品的指理模式都表现为在生长早期形成分支结构,分支结构通过合并和聚结形成稳定的界面。考虑到XG聚合物和纳米聚合物溶胶的高剪切减薄强度(n值在0.17 ~ 0.27之间),这是预期的行为。然而,HPAM溶液和纳米聚合物溶胶表现出不同的指法模式,包括尖端分裂或抑制尖端分裂和侧分支。这种差异归因于修饰后的NP与两种聚合物的聚合链之间的不同相互作用。添加任何类型的NP都没有提高HPAM聚合物溶液的面扫效率,因为聚合物溶液的粘度降低了,注入液和油之间的界面张力降低了。然而,加入1.0 wt.%和2.0 wt.% NP的XG聚合物溶液可以显著提高扫描效率。结果表明,在黄原胶聚合物驱油中加入二氧化硅NP,可以改善聚合物驱油性能。
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