Polymeric surfactants as alternative to improve waterflooding oil recovery efficiency

CT&F - Ciencia, Tecnología y Futuro Pub Date : 2020-12-17 DOI:10.29047/01225383.272

Henderson Iván Quintero Pérez, Miguel José Rondon Anton, Jaime Alberto Jimenez, J. Bermudez, Julian Alfredo Gonzalez, Jenny Liset Rodrigues, Carlos Espinosa Leon

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引用次数: 1

Abstract

Chemical formulations, including surfactants, polymers, alkalis, or their combinations, are widely used in different oil recovery processes to improve water injection performance. However, based on challenging profit margins in most mature waterfloods in Colombia and overseas, it is necessary to explore alternatives that could offer better performance and greater operational flexibility than the conventional technologies used for enhanced oil recovery (EOR) processes. Polymeric surfactants are compounds widely used in the manufacture of domestic and industrial cleaning, pharmaceutical, cosmetic, and food products. These compounds represent an interesting alternative as they can simultaneously increase the viscosity in water solution and reduce the interfacial tension (IFT) in the water/oil system, which would increase the efficiency of EOR processes. This article shows a methodological evaluation through laboratory studies, numerical reservoir simulation, and conceptual engineering design to apply polymeric surfactants (Block Copolymer Polymeric Surfactants or BCPS) as additives to improve efficiency in water injection processes. Block copolymer type products of ethylene oxide (EO) - propylene oxide (PO) - ethylene oxide (EO) in aqueous solution were studied to determine their rheological and surfactant behavior under the operating conditions of a Colombian field. In the conditions studied, these products allow to reduce the interfacial tension up to 2x10-1 mN/m values and also cause a shear-thinning rheological behavior following the power law at very low shear rates (0.1 s-1– 1 s-1), which corresponds to an increase up to four orders of magnitude in the capillary number (Nc). The IFT and the viscosity reached are maintained in wide ranges of salinity, BCPS concentration, and shear rates, making it a robust performance formulation. In a model porous medium, BCPS tested have moderate adsorption, less than conventional surfactants but higher than HPAM polymers, in any way allowing a favorable wettability condition. Additionally, it was observed that they offer a resistance factor up to 16 times, causing greater displacement efficiency than water injection, allowing better sweeping in low permeability areas without injectivity restrictions. Numerical simulation shows that it is possible to reach incremental production up to 238,5 TBO by injecting a continuous slug of 0.15 pore volumes of BCPS and HPAM, each with 2,000 ppm concentration and a flow rate of 2,500 BPD. As BCPS are simple handling and dilution products, these could be injected directly in water injection flow using a high precision dosing pump with high pressure and flow rate operational variables.

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聚合物表面活性剂可替代水驱提高采收率

化学配方，包括表面活性剂、聚合物、碱或它们的组合，广泛应用于不同的采油工艺，以提高注水性能。然而，鉴于哥伦比亚和海外大多数成熟水驱的利润率极具挑战性，有必要探索能够提供更好性能和更大操作灵活性的替代方案，而不是用于提高石油采收率(EOR)工艺的传统技术。高分子表面活性剂是一种广泛应用于家用和工业清洁、制药、化妆品和食品生产的化合物。这些化合物代表了一种有趣的替代方案，因为它们可以同时增加水溶液中的粘度，降低水/油系统中的界面张力(IFT)，从而提高EOR过程的效率。本文通过实验室研究、油藏数值模拟和概念工程设计，展示了应用聚合物表面活性剂(嵌段共聚物聚合物表面活性剂或BCPS)作为添加剂来提高注水效率的方法学评价。在哥伦比亚某油田的操作条件下，研究了环氧乙烷(EO) -环氧丙烷(PO) -环氧乙烷(EO)的嵌段共聚物型产物在水溶液中的流变性和表面活性剂行为。在研究的条件下，这些产品允许将界面张力降低到2 × 10-1 mN/m值，并且在非常低的剪切速率(0.1 s-1 -1 s-1)下也会产生剪切-变薄流变行为，这相当于毛细管数(Nc)增加了4个数量级。在盐度、BCPS浓度和剪切速率的大范围内，IFT和达到的粘度都能保持，使其成为一种性能稳定的配方。在模拟多孔介质中，BCPS具有中等的吸附性能，低于常规表面活性剂，但高于HPAM聚合物，无论如何都具有良好的润湿性条件。此外，研究人员还观察到，它们的阻力系数高达16倍，比注水驱替效率更高，可以在没有注入限制的情况下更好地波及低渗透区域。数值模拟表明，通过连续注入0.15孔容的bps和HPAM段塞，分别为2000 ppm浓度和2500 BPD的流量，可以达到238.5 TBO的增量产量。由于BCPS是一种易于处理和稀释的产品，因此可以使用具有高压力和高流量操作变量的高精度加药泵直接注入注水流中。

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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CT&F - Ciencia, Tecnología y Futuro

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