Study on the Oil Displacement Effect and Application of Soft Microgel Flooding Technology

Jian Zhang, Zhe Sun, Xiujun Wang, Xiaodong Kang
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引用次数: 1

Abstract

Due to the reservoir heterogeneity, there is still a lot of remaining oil that cannot be displaced by water flooding. Therefore, taking the whole injection-production flow field as the research object, the dominant channel is divided into macro and micro channel. Then the corresponding oil displacement system is adopted to realize the continuous flow diversion and effective expansion of swept volume. For micro channels, the soft microgel particle dispersion can be used. It is a novel flooding system developed in recent years. Due to its excellent performance and advanced mechanism, the oil recovery rate can be greatly improved. Soft microgel particle dispersion consists of microgel particles and its carrier fluid. After coming into porous media, its unique phenomenon of particle phase separation appears, which leads to the properties of "plugging large pore and leave the small one open", and the deformation and migration characteristic in the poros media. Therefore, particle phase separation of soft microgel particle dispersion is studied by using the microfluidic technology and numerical simulation. On this basis, by adopting the NMR and 3D Printing technology, the research on its oil displacement mechanism is further carried out. Furthermore, the typical field application cases are analyzed. Results show that, soft microgel particles have good performance and transport ability in porous media. According to the core displacement experiment, this paper presents the matching coefficient between microgels and pore throat under effective plugging modes. Also, the particle phase separation happens when injecting microgels into the core, which makes the particles enter the large pore in the high permeability layer and fluid enters into small pore. Therefore, working in cooperation, this causes no damage to the low permeability layer. On this basis, theoretically guided by biofluid mechanics, the mathematical model of soft microgel particle is established to simulate its concentration distribution, which obtained the quantitative research results. Furthermore, the micro displacement experiment shows that, microgels has unique deformation and migration characteristic in the poros media, which can greatly expand swept volume. The macro displacement experiment shows that, microgels have good oil displacement performance. Finally, the soft microgel particle dispersion flooding technology has been applied in different oilfields since 2007. Results show that these field trials all obtain great oil increasing effect, with the input-output ratio range of 2.33-14.37. And two field application examples are further introduced. Through interdisciplinary innovative research methods, the oil displacement effect and field application of soft microgel particle dispersion is researched, which proves its progressiveness and superiority. The research results play an important role in promoting the application of this technology.
软微凝胶驱油技术驱油效果及应用研究
由于储层非均质性,仍有大量剩余油不能通过水驱驱替。因此,以整个注采流场为研究对象,将主导通道分为宏观通道和微通道。然后采用相应的驱油系统,实现连续导流和有效扩大扫气量。对于微通道,可采用软质微凝胶颗粒分散。它是近年来发展起来的一种新型驱油系统。由于其优异的性能和先进的机理,可以大大提高采收率。软微凝胶颗粒分散体由微凝胶颗粒及其载液组成。进入多孔介质后,其独特的颗粒相分离现象出现,导致其具有“大孔堵小孔开”的特性,以及在多孔介质中的变形和迁移特征。因此,采用微流控技术和数值模拟的方法对软微凝胶颗粒分散的颗粒相分离进行了研究。在此基础上,采用核磁共振和3D打印技术,进一步开展其驱油机理研究。并对典型的现场应用案例进行了分析。结果表明,软质微凝胶颗粒在多孔介质中具有良好的性能和输运能力。通过岩心驱替实验,给出了有效封堵模式下微凝胶与孔喉的匹配系数。微凝胶注入岩心发生颗粒相分离,颗粒进入高渗层的大孔隙,流体进入小孔隙。因此,在协同工作中,这不会对低渗透层造成损害。在此基础上,以生物流体力学为理论指导,建立软质微凝胶颗粒的数学模型,模拟其浓度分布,获得定量研究结果。此外,微位移实验表明,微凝胶在孔隙介质中具有独特的变形和迁移特性,可以极大地扩大扫描体积。宏观驱油实验表明,微凝胶具有良好的驱油性能。最后,自2007年以来,软微凝胶颗粒分散驱油技术在不同油田得到了应用。结果表明:现场试验均取得了较好的增产效果,投入产出比在2.33 ~ 14.37之间。并进一步介绍了两个现场应用实例。通过跨学科的创新研究方法,研究了软质微凝胶颗粒分散体的驱油效果及现场应用,证明了其先进性和优越性。研究成果对该技术的推广应用具有重要的推动作用。
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