The Role of Polymer on Surfactant-Foam Stability During Carbon Dioxide Mobility Control Process

Z. Alyousef, Othman Swaie, A. Alabdulwahab, S. Kokal
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引用次数: 1

Abstract

The in-situ generation of foam is one of the most promising techniques to solve gas mobility challenges in petroleum reservoirs and subsequently improve the volumetric sweep efficiency. The stabilization of foam at reservoir conditions is a major challenge. The harsh reservoir conditions, such as high temperature, high brine salinity, together with surfactant adsorption on the rock may result in unstable foam and, consequently, poor sweep efficiency. Foam additives, such as polymers, might help strengthen the physical properties of foam film and improve foam stability. This work evaluates the effectiveness of a polymer on enhancing CO2-foam stabilization at harsh reservoir conditions. Static and dynamic foam tests were conducted to evaluate the role of polymer on foam stability. Three foaming surfactants were used to assess the ability of the polymer on enhancing foam stabilization. The static foam tests were conducted at conditions similar to reservoir conditions using test tubes. Foam column, and foam life were measured to evaluate the role of the polymer on foam stabilization. Foam viscosity in absence and presence of the polymer was measured using foam rheometer apparatus. The dynamic foam tests were conducted to assess the ability of tested materials to generate viscous foams and also measure the CO2 mobility in porous media using a coreflooding system. The mobility reduction factor (MRF) was measured at high pressure and high temperature (HPHT) conditions, 3200 psi and 100°C. The static foam tests and foam rheology measurements indicated that the addition of the polymer enhanced foam stability as a result of increasing the bulk viscosity of the aqueous solutions. The results found that the foam life increased with the polymer concentration. However, the increase of polymer concentration makes the solution very viscous, hence, the foam generation becomes challenging. The dynamic foam tests showed that the foam generated in absence of the polymer was able to reduce the CO2 mobility 13 fold. However, the addition of the polymer resulted in higher pressure drops during CO2 floods, more resistance to gas flow and, therefore, lower gas mobility compared to that obtained with surfactant alone. The addition of the polymer reduced the CO2 mobility 50 fold. This higher reduction in the CO2 mobility as a result of adding the polymer can be attributed to the effectiveness of the polymer in improving the foam stabilization and prolong the life of generated foam.
二氧化碳迁移率控制过程中聚合物对表面活性剂-泡沫稳定性的影响
原位生成泡沫是解决油藏中气体流动性挑战并提高体积扫描效率的最有前途的技术之一。储层条件下泡沫的稳定是一个主要的挑战。恶劣的储层条件,如高温、高盐水盐度,加上表面活性剂在岩石上的吸附,可能导致泡沫不稳定,从而影响波及效率。泡沫添加剂,如聚合物,可能有助于加强泡沫膜的物理性能,提高泡沫的稳定性。这项工作评估了聚合物在恶劣储层条件下提高二氧化碳泡沫稳定性的有效性。通过静态和动态泡沫试验来评价聚合物对泡沫稳定性的影响。用三种发泡表面活性剂评价了聚合物增强泡沫稳定性的能力。静态泡沫试验是在类似油藏条件下使用试管进行的。通过测定泡沫柱和泡沫寿命来评价聚合物对泡沫稳定的作用。用泡沫流变仪测量了无聚合物和有聚合物时的泡沫粘度。动态泡沫测试是为了评估测试材料产生粘性泡沫的能力,并使用岩心驱替系统测量多孔介质中二氧化碳的迁移率。在高压和高温(HPHT)条件下,3200 psi和100°C,测量了迁移率降低因子(MRF)。静态泡沫测试和泡沫流变学测量表明,聚合物的加入增加了水溶液的体积粘度,从而增强了泡沫的稳定性。结果表明,泡沫寿命随聚合物浓度的增加而增加。然而,随着聚合物浓度的增加,溶液变得非常粘稠,因此,泡沫的产生变得具有挑战性。动态泡沫测试表明,在没有聚合物的情况下产生的泡沫能够将CO2迁移率降低13倍。然而,与单独使用表面活性剂相比,聚合物的加入导致CO2驱油过程中的压降更高,对气体流动的阻力更大,因此气体流动性更低。聚合物的加入使CO2迁移率降低了50倍。由于添加了聚合物,二氧化碳迁移率的降低幅度更高,这可以归因于聚合物在提高泡沫稳定性和延长泡沫寿命方面的有效性。
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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