通过基于地球化学的耦合建模方法对混合低矿化度聚合物驱的新认识

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
A. Hassan, E. Al-Shalabi, W. Alameri, M. Kamal, S. Patil, S. M. S. Hussain
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引用次数: 0

摘要

低矿化度聚合物驱(LSP)是一种协同紧急提高采收率(EOR)的技术。先前的实验室实验表明,驱替效率、聚合物流变性、注入性和粘弹性都有显著改善。然而,当涉及到模拟LSP驱油时,开发一个捕捉聚合物-盐水-岩石(PBR)相互作用的机制预测模型仍然具有挑战性。因此,本研究使用耦合的MATLAB油藏模拟工具箱(MRST)-IPhreeqc模拟器,通过改变总体盐度以及二价和单价离子浓度,研究LSP驱油过程中水化学对PBR相互作用的影响。为了描述相关的地球化学,通过将新的溶液种类(Poly)引入Phreeqc数据库,考虑了聚合物在水相中的存在。所建立的模型参数经过验证,并与文献中报道的实验数据进行了历史匹配。此外,还分析了低盐度(LS)水、LSP注入(1 × LSP)和5次加标LSP注入(5 × LSP)不同注入方案对聚合物粘度的影响。结果表明,在LSP驱油过程中,聚合物粘度直接受到Ca2+和Mg2+的影响,间接受到SO42−的影响,这是由于PBR与白云岩造岩矿物的相互作用。一价离子(即Na+和K+)对聚合物粘度的影响较小。白云石溶解释放的Ca2+和Mg2+离子形成聚合物配合物(丙烯酸、C3H4O2),显著降低聚合物粘度。注入LSP溶液中SO42−浓度的增加影响了聚合物与带正电的水溶液之间的相互作用,导致聚合物粘度损失最小化。对于LSP洪水防范措施,阳离子的效果与电荷比(CR)有关。因此,获得粘度损失最小的最佳CR是关键。本文是为数不多的详细介绍LSP驱油技术的机械地球化学建模的论文之一。经过验证的MRST-IPhreeqc模拟器评估了LSP过程中之前被忽视的水化学对聚合物粘度的影响。使用该耦合模拟器,可以评估其他几种地球化学反应和参数,包括岩石和注入水成分、注入方案和其他聚合物特征。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
New Insights into Hybrid Low-Salinity Polymer Flooding through a Coupled Geochemical-Based Modeling Approach
Low-salinity polymer (LSP) flooding is a synergic emergent enhanced oil recovery (EOR) technique. Previous laboratory experiments showed noticeable improvements in displacement efficiency, polymer rheology, injectivity, and viscoelasticity. Nevertheless, when it comes to modeling LSP flooding, it is still challenging to develop a mechanistic predictive model that captures polymer-brine-rock (PBR) interactions. Therefore, this study uses a coupled MATLAB reservoir simulation toolbox (MRST)-IPhreeqc simulator to investigate the effect of water chemistry on PBR interactions during LSP flooding through varying overall salinity and the concentrations of divalent and monovalent ions. For describing the related geochemistry, the presence of polymer in the aqueous phase was considered by introducing novel solution species (Poly) to the Phreeqc database. The developed model’s parameters were validated and history matched with experimental data reported in the literature. Moreover, different injection schemes were analyzed, including low-salinity (LS) water, LSP injection (1 × LSP), and 5-times spiked LSP injection (5 × LSP) with their related effects on polymer viscosity. Results showed that polymer viscosity during LSP flooding is affected directly by Ca2+ and Mg2+ and indirectly by SO42− owing to PBR interactions on a dolomite rock-forming mineral. Monovalent ions (viz. Na+ and K+) have minor effects on polymer viscosity. Ca2+ and Mg2+ ions discharged from dolomite dissolution create polymer complexes (acrylic acid, C3H4O2) to reduce polymer viscosity significantly. The increased SO42− concentration in the injected LSP solution affects the interactions between the polymer and positively charged aqueous species, leading to minimized polymer viscosity loss. For LSP flood derisking measures, the cation’s effect was related to the charge ratio (CR). Thus, it is key to obtain an optimal CR where viscosity loss is minimal. This paper is among the few to detail the mechanistic geochemical modeling of the LSP flooding technique. The validated MRST-IPhreeqc simulator evaluates the previously overlooked effects of water chemistry on polymer viscosity during the LSP process. Using this coupled simulator, several other geochemical reactions and parameters can be assessed, including rock and injected-water compositions, injection schemes, and other polymer characteristics.
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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