In shale oil reservoirs, Improved Oil Recovery (IOR) methods are relatively considered as new concepts compared with in conventional oil reservoirs. Different IOR techniques have been investigated by using lab experiments, numerical simulation studies, and limited pilot tests. Unconventional IOR methods include injecting CO2, surfactant, natural gas, and water. However, CO2 injection is the most investigated option due to different reasons. CO2 has lower miscibility pressure with shale oils, and has special properties in its supercritical conditions, and CO2 injection also solves greenhouse problems. In this paper, numerical simulation methods of compositional models were incorporated with LS-LR-DK (logarithmically spaced, locally refined, and dual permeability) reservoir models and Local Grids Refinement (LGR) of hydraulic fractures conditions to investigate the feasibility of CO2 injection in shale oil reservoirs. Different mechanisms for CO2 interactions with organic surface, shale brine, and shale oil were implemented in different scenarios of numerical models. Molecular diffusion mechanisms, adsorption effects, and aqueous solubility effects were simulated in this study. In addition, linear elastic models and stress-dependent correlations were used to consider geomechanics coupling effects on production and injection processes of CO2-EOR in shale oil reservoirs. Some of the results for this simulation study were validated by matching the performance of some CO2 fields’ pilots performed in Bakken formation, in North Dakota and Montana portions. This study extremely found that some of the CO2-EOR pilot tests have a match with the typical simulated diagnostic plots which have CO2 molecular-diffusion rate that is significantly low. Furthermore, this research indicated that CO2 molecular diffusion mechanism has a clearly positive effect on CO2-EOR in huff-n-puff protocol; however, this mechanism has a relatively negative effect on continuous flooding mode of CO2-EOR. Both of dissolution and adsorption mechanisms have a negative effect on CO2 performance in terms of enhancing oil recovery in unconventional formations. Geomechanics coupling has a clear effect on CO2-EOR performance, and different geomechanics models have a different validity in these shale plays. Stress dependent correlations give the best match with CO2-EOR pilots in Bakken formation while linear elastic models would give the best match in Eagle Ford formation. This study explains the effects of different nano and macro mechanisms on the performance of CO2-EOR in unconventional reservoirs since these plays are much complex and very different from conventional formations. Also, general guidelines have been provided in this study to enhance success of CO2-EOR in these types of reservoirs.
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机译:在页岩储油储存器中,与传统的油藏相比,改善的石油回收(IOR)方法相对被视为新概念。通过使用实验室实验,数值模拟研究和有限的试验试验研究了不同的IOR技术。非常规的IOR方法包括注入CO2,表面活性剂,天然气和水。然而,由于不同的原因,CO2注射是最多调查的选择。 CO2具有较低的混合物压力与页岩油,在其超临界条件下具有特殊性质,CO2注射也解决了温室问题。本文,组合模型的数值模拟方法纳入了LS-LR-DK(对数间隔,局部精制,双渗透率)储层液库模型和局部网格改进(LGR)液压裂缝条件,以研究CO2注射的可行性页岩油藏。 CO2与有机表面相互作用的不同机制,页岩盐水和页岩油在不同的数值模型的不同场景中实现。在该研究中模拟了分子扩散机制,吸附效应和含水溶解度效应。此外,使用线性弹性模型和应力相关的相关性来考虑对页岩油藏CO2-EOR的生产和注射过程的地质力学耦合效应。通过在北达科他州和蒙大拿州的Bakken地层执行的某些CO2领域的飞行员的性能匹配,验证了这种模拟研究的一些结果。本研究极大地发现,一些CO2-EOR导频试验与典型的模拟诊断图匹配,具有CO 2的分子扩散速率明显低。此外,该研究表明CO2分子扩散机制对Huff-N-Puff方案中的CO2-EOR具有明显的积极作用;然而,该机制对CO2-EOR的连续洪水模式具有相对负面影响。溶解和吸附机制两者对CO 2性能的负面影响在加强非传统地层中的采油方面具有负面影响。地质力学耦合对CO2-EOR性能有明显的影响,不同的地质力学模型在这些页面播放中具有不同的有效性。应力相关的相关性与Bakken地层中的CO2-EOR飞行员提供最佳匹配,而线性弹性模型将在Eagle Ford Madoction中提供最佳匹配。本研究阐述了不同纳米和宏机制对非传统水库中CO2-EOR性能的影响,因为这些戏剧性与传统结构非常复杂,非常不同。此外,本研究中提供了一般指导方针,以提高这些类型的水库中CO2-EOR的成功。
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