Unlock the Potentials to Further Improve CO2 Storage and Utilization with Supercritical CO2 Emulsions When Applying CO2-Philic Surfactants

G. Ren, Bohong Ren, Songyan Li, Chao Zhang
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引用次数: 2

Abstract

Supercritical CO2 (ScCO2) emulsion has attracted lots of attention, which could benefit both climate control via CO2 storage and industry revenue through significantly increased oil recovery simultaneously. Historically, aqueous soluble surfactants have been widely used as stabilizers, though they suffer from slow propagation, relatively high surfactant adsorption and well injectivity issues. In contrast, the CO2-soluble surfactants could improve the emulsion performance remarkably, due to their CO2-philicity. Here, comprehensive comparison studies are carried out from laboratory experiments to field scale simulations between a commercially available aqueous soluble surfactant (CD 1045) and a proprietary nonionic CO2-philic surfactant whose solubility in ScCO2 and partition coefficient between ScCO2/Brine have been determined. Surfactant affinity to employed oil is indicated by a phase behavior test. Static adsorptions on Silurian dolomite outcrop are conducted to gain the insights of its electro-kinetic properties. Coreflooding experiments are carried out with both consolidated 1 ft Berea sandstone and Silurian dolomite to compare the performances as a result of surfactant natures under two-phase conditions, while harsher conditions are examined on fractured carbonate with presence of an oleic phase. Moreover, the superiorities of ScCO2 foam with CO2-philic surfactant due to dual phase partition capacity are illustrated with field scale simulations. ScCO2 and WAG injections behaviors are used as baselines, while the performances of two types of CO2 emulsions are compared with SAG injection, characterized by phase saturations, CO2 storage, oil production, CO2 utilization ratio and pressure distribution. A novel injection strategy, named CO2 continuous injection with dissolved surfactant (CIDS), which is unique for a CO2-philic surfactant, is also studied. It is found that the CO2-soluble surfactant displays much lower oil affinity and adsorption on carbonate than CD 1045. Furthermore, in a laboratory scale, a much higher foam propagation rate is observed with the novel surfactant, which is mainly ascribed to its CO2 affinity, assisted by the high mobility of the CO2 phase. Field scale simulations clearly demonstrate the potentials of CO2 emulsion on CO2 storage and oil recovery over conventional tertiary productions. Relative to traditional aqueous soluble surfactant emulsion, the novel surfactant emulsion contributes to higher injectivity, CO2 storage capability, oil recovery and energy utilization efficiency. The CIDS could further reduce water injection cost and energy consumption. The findings here reveal the potentials of further improving CO2 storage and utilization when applying ScCO2-philic surfactant emulsion, to compromise both environmental and economic concerns.
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当使用亲二氧化碳表面活性剂时,解锁超临界二氧化碳乳液进一步提高二氧化碳储存和利用的潜力
超临界二氧化碳(ScCO2)乳化液引起了人们的广泛关注,它既可以通过二氧化碳储存来控制气候,也可以通过显著提高石油采收率来提高工业收入。从历史上看,水溶性表面活性剂被广泛用作稳定剂,尽管它们存在传播缓慢、相对较高的表面活性剂吸附性和井注入性问题。而co2溶性表面活性剂由于具有亲和性,可以显著改善乳液的性能。在这里,从实验室实验到现场模拟,对市售的水溶性表面活性剂(CD 1045)和专有的非离子型亲二氧化碳表面活性剂(其在ScCO2中的溶解度和ScCO2/盐水之间的分配系数已经确定)进行了全面的比较研究。用相行为试验表明了表面活性剂对所用油的亲和力。通过对志留系白云岩露头进行静态吸附,了解其电动力学性质。研究人员对1英尺厚的Berea胶结砂岩和志留系白云岩进行了驱心实验,比较了两相条件下表面活性剂性质的影响,同时对裂缝性碳酸盐岩进行了更严酷的条件测试,其中存在油相。此外,还通过现场模拟说明了亲co2表面活性剂的双相分配能力对ScCO2泡沫的优越性。以ScCO2和WAG注入行为为基准,对比两种类型的CO2乳状液与SAG注入的相饱和度、CO2储存量、产油量、CO2利用率和压力分布特征。研究了一种新的注入策略,即溶解表面活性剂连续注入二氧化碳(CIDS),这是一种独特的亲二氧化碳表面活性剂。结果表明,该co2溶性表面活性剂的油亲和力和对碳酸盐的吸附性能明显低于cd1045。此外,在实验室规模下,观察到新型表面活性剂具有更高的泡沫传播速率,这主要归因于其CO2亲和力,以及CO2相的高流动性。现场规模模拟清楚地表明,与常规的三次采油相比,CO2乳化液在CO2储存和采油方面的潜力更大。与传统的水溶性表面活性剂乳液相比,新型表面活性剂乳液具有更高的注入能力、CO2储存能力、采收率和能源利用效率。CIDS可以进一步降低注水成本和能源消耗。本研究结果揭示了应用亲scco2表面活性剂乳液进一步提高CO2储存和利用的潜力,以兼顾环境和经济问题。
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