Investigating the Effect of Water Softening on Polymer Adsorption onto Carbonates through Single-Phase and Two-Phase Experiments

SPE Journal Pub Date : 2024-06-01 DOI:10.2118/211470-pa
Anoo Sebastian, Muhammad Mushtaq, E. Al-Shalabi, W. Alameri, K. Mohanty, S. K. Masalmeh, A. AlSumaiti
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Abstract

Polymer retention is considered a major challenge in polymer flooding applications, especially in carbonates. This is due to the prevailing conditions of low permeability (<100 md), high temperature (>85°C), and high salinity (>100,000 ppm) generally found in these formations, which limit the effectiveness of commonly used polymers such as hydrolyzed polyacrylamide (HPAM) and xanthan gum. To address these challenges, a polymer based on acrylamide tertiary butyl sulfonate (ATBS) has been used due to its tolerance to high-temperature and -salinity conditions. However, the high cost of manufacturing these polymers, combined with their anionic properties that promote adsorption onto positively charged carbonate rocks, necessitates the exploration of methods to reduce polymer retention. In this study, we aim to determine the sufficient concentration of hardness ions (Ca2+ and Mg2+) required to significantly reduce the adsorption of this polymer. The study is unique in its focus on mitigating polymer retention in carbonate formations using softened brine, as no prior research has investigated this aspect. Four different brines were investigated with a salinity of 8,000 ppm total dissolved salts (TDS) and varying ionic composition designed mainly by eliminating the hardness-causing ions, Ca2+ and Mg2+. A geochemical study was performed using the PHREEQC software to analyze the interaction between these injected brines and the rock. Furthermore, comprehensive rheological and static adsorption studies were performed at a temperature of 25°C using the potential ATBS-based polymer to evaluate the polymer performance and adsorption in these brines. Later, dynamic adsorption studies were conducted in both single-phase and two-phase conditions to further quantify polymer adsorption. The geochemical study showed an anhydrite saturation index (SI) of less than 0.5 for all the brines used when interacting with the rock, indicating a very low tendency for calcium sulfate precipitation. Furthermore, the rheological studies showed that polymer viscosity significantly increased with reduced hardness, where a polymer solution viscosity of 7.5 cp was obtained in zero hardness brine, nearly 1.5 times higher than the polymer viscosity of the base makeup brine of 8,000 ppm. Moreover, it was observed that, by carefully tuning the concentrations of the divalent cations, the polymer concentration consumption for the required target viscosity was reduced by 40–50%. For the single-phase static adsorption experiments, the polymer solution in softened brines resulted in lower adsorption in the range of 37–62 µg/g-rock as opposed to 102 µg/g-rock for the base makeup brine. On the other hand, the single-phase dynamic adsorption results showed an even lowered polymer adsorption of 33 µg/g-rock for the softened brine compared with 45 µg/g-rock for the base makeup brine. Additionally, the single-phase dynamic adsorption studies showed a remarkable improvement in polymer injectivity using softened brine. The polymer retention in wettability-altered cores was further reduced. The study highlights that water softening improves the performance of polymers, specifically in terms of lowering polymer adsorption. It concludes that a threshold hardness level (Ca2+ and Mg2+) of approximately 100 ppm is sufficient to achieve a significant reduction in polymer adsorption for the tested experimental conditions. In this paper, we show that the softened water increases the polymer viscosity and reduces polymer adsorption, which leads to an overall reduction in polymer consumption. Hence, the softened makeup water has the potential to enhance the application envelope of this potential polymer for polymer flood, especially in the case of carbonate reservoirs.
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通过单相和双相实验研究水软化对碳酸盐上聚合物吸附的影响
聚合物滞留被认为是聚合物淹没应用中的一大挑战,尤其是在碳酸盐岩中。这是由于这些地层中普遍存在低渗透性(85°C)和高盐度(>100,000 ppm)的条件,限制了水解聚丙烯酰胺(HPAM)和黄原胶等常用聚合物的效果。为了应对这些挑战,一种基于丙烯酰胺叔丁基磺酸盐(ATBS)的聚合物因其对高温和盐度条件的耐受性而被采用。然而,由于制造这些聚合物的成本较高,加之其阴离子特性会促进吸附在带正电荷的碳酸盐岩上,因此有必要探索减少聚合物滞留的方法。在这项研究中,我们旨在确定大幅减少这种聚合物的吸附所需的硬度离子(Ca2+ 和 Mg2+)的足够浓度。这项研究的独特之处在于,它侧重于利用软化盐水减轻聚合物在碳酸盐岩层中的滞留,因为此前没有任何研究对这方面进行过调查。研究了四种不同的盐水,盐度为 8,000 ppm 总溶解盐(TDS),离子成分各不相同,主要是通过去除导致硬度的离子 Ca2+ 和 Mg2+。使用 PHREEQC 软件进行了地球化学研究,以分析这些注入盐水与岩石之间的相互作用。此外,还在 25°C 的温度下使用基于 ATBS 的潜在聚合物进行了全面的流变学和静态吸附研究,以评估聚合物在这些盐水中的性能和吸附性。随后,在单相和两相条件下进行了动态吸附研究,以进一步量化聚合物的吸附情况。地球化学研究表明,所有盐水与岩石相互作用时的无水饱和度指数(SI)均小于 0.5,这表明硫酸钙沉淀的趋势非常低。此外,流变学研究表明,聚合物的粘度随着硬度的降低而显著增加,在零硬度盐水中,聚合物溶液的粘度为 7.5 cp,比 8,000 ppm 基准化妆盐水的聚合物粘度高出近 1.5 倍。此外,通过仔细调整二价阳离子的浓度,还可将达到目标粘度所需的聚合物浓度消耗降低 40-50%。在单相静态吸附实验中,软化盐水中的聚合物溶液的吸附量较低,在 37-62 微克/克-岩石的范围内,而基础补充盐水的吸附量为 102 微克/克-岩石。另一方面,单相动态吸附结果显示,软化盐水对聚合物的吸附量更低,为 33 微克/克-岩石,而基本补充盐水的吸附量为 45 微克/克-岩石。此外,单相动态吸附研究表明,使用软化盐水可显著提高聚合物注入率。聚合物在润湿性改变的岩心中的滞留率进一步降低。研究强调,水软化可改善聚合物的性能,特别是在降低聚合物吸附性方面。研究得出结论,在测试的实验条件下,约 100 ppm 的阈值硬度(Ca2+ 和 Mg2+)足以显著降低聚合物吸附性。本文表明,软化水可增加聚合物粘度,减少聚合物吸附,从而全面降低聚合物消耗量。因此,软化后的补给水有可能提高这种潜在聚合物在聚合物泛滥中的应用范围,尤其是在碳酸盐岩水库中。
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