A Numerical Investigation of Low Salinity Polymer Flooding Effects from a Geochemical Perspective

Day 4 Thu, August 19, 2021 Pub Date : 2021-08-09 DOI:10.4043/31191-ms

Omar Chaabi, E. Al-Shalabi, W. Alameri

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Abstract

Low salinity polymer (LSP) flooding is getting more attention due to its potential of enhancing both displacement and sweep efficiencies. Modeling LSP flooding is challenging due to the complicated physical processes and the sensitivity of polymers to brine salinity. In this study, a coupled numerical model has been implemented to allow investigating the polymer-brine-rock geochemical interactions associated with LSP flooding along with the flow dynamics. MRST was coupled with the geochemical software IPhreeqc. The effects of polymer were captured by considering Todd-Longstaff mixing model, inaccessible pore volume, permeability reduction, polymer adsorption as well as salinity and shear rate effects on polymer viscosity. Regarding geochemistry, the presence of polymer in the aqueous phase was considered by adding a new solution specie and related chemical reactions to PHREEQC database files. Thus, allowing for modeling the geochemical interactions related to the presence of polymer. Coupling the two simulators was successfully performed, verified, and validated through several case studies. The coupled MRST-IPhreeqc simulator allows for modeling a wide variety of geochemical reactions including aqueous, mineral precipitation/dissolution, and ion exchange reactions. Capturing these reactions allows for real time tracking of the aqueous phase salinity and its effect on polymer rheological properties. The coupled simulator was verified against PHREEQC for a realistic reactive transport scenario. Furthermore, the coupled simulator was validated through history matching a single-phase LSP coreflood from the literature. This paper provides an insight into the geochemical interactions between partially hydrolyzed polyacrylamide (HPAM) and aqueous solution chemistry (salinity and hardness), and their related effect on polymer viscosity. This work is also considered as a base for future two-phase polymer solution and oil interactions, and their related effect on oil recovery.

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地球化学视角下低矿化度聚合物驱效应的数值研究

低矿化度聚合物(LSP)驱油由于具有提高驱油效率和波及效率的潜力而受到越来越多的关注。由于复杂的物理过程和聚合物对盐水盐度的敏感性，LSP驱油模型具有挑战性。在本研究中，实现了一个耦合数值模型，以研究与LSP驱相关的聚合物-盐水-岩石地球化学相互作用以及流动动力学。MRST与地球化学软件IPhreeqc相结合。通过考虑Todd-Longstaff混合模型、不可达孔隙体积、渗透率降低、聚合物吸附以及盐度和剪切速率对聚合物粘度的影响，捕获了聚合物的影响。在地球化学方面，通过在PHREEQC数据库文件中添加新的溶液种类和相关化学反应，考虑了聚合物在水相中的存在。因此，允许模拟与聚合物存在相关的地球化学相互作用。通过几个案例研究，成功地执行、验证和验证了两个模拟器的耦合。耦合的MRST-IPhreeqc模拟器可以模拟各种各样的地球化学反应，包括水、矿物沉淀/溶解和离子交换反应。捕获这些反应可以实时跟踪水相盐度及其对聚合物流变性能的影响。通过PHREEQC对耦合模拟器进行了验证，得到了一个真实的响应传输场景。此外，通过历史匹配文献中的单相LSP核心洪水，验证了耦合模拟器。本文研究了部分水解聚丙烯酰胺(HPAM)与水溶液化学(盐度和硬度)的地球化学相互作用及其对聚合物粘度的相关影响。这项工作也被认为是未来两相聚合物溶液与油的相互作用以及它们对石油采收率的相关影响的基础。

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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Day 4 Thu, August 19, 2021

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