Experimental Evaluation of Foam Diversion for EOR in Heterogeneous Carbonate Rocks

IF 2.5 Q3 CHEMISTRY, PHYSICAL

Colloids and Interfaces Pub Date : 2022-11-02 DOI:10.3390/colloids6040063

Motaz Taha, P. Patil, Q. Nguyen

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引用次数: 1

Abstract

Immiscible gas injection applied to heterogeneous carbonate reservoirs can be inefficient due to poor conformance control. Foam mobility control is proposed in this work as a solution for gas conformance issues in such reservoirs. A unique experimental program was developed to evaluate alkyl polyglucoside (APG) stabilized foam for foaming ability, emulsion-forming tendency and resistance to oil. Dynamic methane foam behavior is systematically studied through single and dual injection core flooding experiments, simulating foam diversion during immiscible methane flooding in a layered reservoir with a significant layer permeability contrast. Results show a stable foam-oil system with no viscous emulsions at very high formation brine salinity (144,000 ppm total dissolved solids). Single-core floods for the high permeability layer (Unit-A) showed that foam viscosity of 27 cP could be achieved at 11% oil saturation (So). Under similar oil-wet condition, the low permeability zone (Unit-B) could generate foam of 21 cP at 18.9% So, indicating an increase in injected fluid mobility reduction with permeability. Dual-core injection experiments, which is designed to evaluate accurately fluid diversion capacity of such foams, reveals remarkable dynamic foam behaviors. While the water-wet condition indicates the scalability of foam behaviors (i.e., the ability of foam to control fluid mobility against the variation of rock permeability) between the single and composite core systems, the oil-wet condition confirms good foam resistance to residual oil that resulted in an increase in Unit B production from 46 to 82%, and 74 to 85% for Unit-A. Moreover, dual-core floods representing premature waterfloods (i.e., higher oil saturation) shows even more dramatic incremental oil recovery (44 to 81% in Unit-A and 17.5 to 71% in Unit-B), evidencing the ability of foam to self-viscosify with permeability variation at varying oil saturations.

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非均质碳酸盐岩提高采收率泡沫导流实验评价

非混相注气应用于非均质碳酸盐岩储层时，由于控制不严密，效率不高。在这项工作中，提出了泡沫流动性控制作为解决此类储层中气体一致性问题的方法。研究了烷基聚葡萄糖苷(APG)稳定泡沫的起泡能力、成乳倾向和耐油性能。通过单次和双次注入岩心驱油实验，系统研究了甲烷的动态泡沫行为，模拟了层状储层渗透率对比明显的非混相甲烷驱过程中的泡沫导流。结果表明，在非常高的地层盐水盐度(144,000 ppm总溶解固体)下，泡沫油体系稳定，无粘性乳状液。高渗透层(Unit-A)单岩心驱油结果表明，在11%含油饱和度(So)下，泡沫粘度可达27 cP。在相似的油湿条件下，低渗透层(Unit-B)以18.9%的速度产生21 cP的泡沫，表明注入流体的流动性随着渗透率的降低而增加。为准确评价此类泡沫的导流能力而设计的双芯注入实验，揭示了显著的动态泡沫行为。水湿条件表明了单一岩心和复合岩心体系之间泡沫行为的可扩展性(即泡沫控制流体流动性以对抗岩石渗透率变化的能力)，而油湿条件证实了泡沫对剩余油的良好抵抗能力，导致单元B的产量从46%增加到82%，单元a的产量从74%增加到85%。此外，代表早期水驱(即更高含油饱和度)的双岩心驱油表现出更显著的产油量增量(Unit-A为44 ~ 81%，Unit-B为17.5% ~ 71%)，证明了泡沫在不同含油饱和度下随渗透率变化而自粘的能力。

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