采用多机制方法研究两性多糖家族的采油情况

Q1 Earth and Planetary Sciences Petroleum Research Pub Date : 2024-06-01 DOI:10.1016/j.ptlrs.2023.12.001
Funsho Afolabi , Syed M. Mahmood , Lunech Mario , Nur Asyraf Md Akhir , Bennett Tackie-Otoo , Hamid Sharifigaliuk
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引用次数: 0

摘要

化学强化采油(cEOR)仍然是最有效的三次采油技术之一。然而,这种方法成本高昂,而且很少对环境友好。生物基两亲性聚合物因其成本效益和可持续性,被认为是消除传统 cEOR 挑战的替代品。遗憾的是,很少有文献对这些材料的前景进行深入研究。通过对硫酸纤维素进行疏水改性,合成了一系列新型两亲多糖,并对其 EOR 功能进行了测试。新型生物聚合物具有改变岩石润湿性能的能力。在采收率方面,合成的生物两亲聚合物的一个变体(D-I)能够在 75 °C、60,000 ppm 盐度的苛刻条件下将剩余油饱和度降低到 12%。微观模型视觉分析表明,新型材料的性能得益于流动性控制、IFT 降低和乳化、润湿性改变以及粘弹性的综合作用。新型两亲多糖的性能与商用疏水改性聚合物相当,可以说它是油田应用中一种可行的 cEOR 剂。
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A multi-mechanistic approach to the oil recovery study of a family of amphiphilic polysaccharides

Chemical enhanced oil recovery (cEOR) remains one of the most potent tertiary recovery techniques. However, it is expensive and rarely environmentally friendly. Bio-based amphiphilic polymers have been suggested as an alternative to eradicating the challenges of conventional cEOR because of cost-effectiveness, and sustainability. Unfortunately, few in-depth studies exist in the literature to investigate the prospects of these materials. A new family of amphiphilic polysaccharides was synthesized by hydrophobic modification of cellulose sulphate, and the EOR functionalities were tested. The novel biopolymers exhibited the ability to alter rock wetting properties. In terms of recovery, one of the variants of the synthesized bio amphiphilic polymer (D-I) was able to reduce residual oil saturation to 12% at harsh conditions of 60,000 ppm salinity at 75 °C. Micromodel visual analysis revealed that the performance of the novel materials was due to the combination of mobility control, IFT lowering and emulsification, wettability alteration, and viscoelasticity. With a performance commensurate to that of a commercial hydrophobically modified polymer, it can be said that the novel amphiphilic polysaccharides can stand as a viable cEOR agent for oilfield applications.

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来源期刊
Petroleum Research
Petroleum Research Earth and Planetary Sciences-Geology
CiteScore
7.10
自引率
0.00%
发文量
90
审稿时长
35 weeks
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