Application of oil in situ combustion for the catalytic methane conversion in the porous medium of the gas reservoir

2区 工程技术 Q1 Earth and Planetary Sciences
Aysylu Askarova , Pavel Afanasev , Evgeny Popov , Evgeny Mikitin , Viktor Darishchev , Alexey Cheremisin
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引用次数: 11

Abstract

Catalytic methane conversion (CMC) could be realized in situ in gas reservoirs. Through this process, a new environment-friendly energy carrier - hydrogen-can be generated inside the hydrocarbon field's porous medium. This method can become a new low-carbon, cost-effective method for hydrogen production. For this purpose, the catalyst has to be delivered into the reservoir, and the temperature inside the active zone of the reservoir has to be raised. The effective way to increase the temperature directly inside the reservoir is by injection of air and combustion of saturating liquid hydrocarbons. This research investigates the CMC process at conditions achieved in the reservoir due to oil in situ combustion (ISC). Numerical and physical modeling of in situ hydrogen generation from methane was performed using forward wet ISC of oil to heat the reservoir. The results of the unique experiment on a crushed oil-saturated core-packed model with different inlet flow rates of air, steam, and methane in the combustion tube (CT) are presented in the current study. The experiment consisted of four parts with different regimes and operational parameters: forward ISC of oil, steam methane reforming (SMR) at 450 °C and 8.9 MPa, SMR at 550 °C and 8.9 MPa, SMR at 550 °C and 2.3 MPa. The combination of these processes has led to the generation of hydrogen and methane conversion rates of up to 40% (during the combustion stage). Comparatively, low hydrogen yield was observed within the experiment, possibly due to the secondary reactions. However, irreversible reduction of oil viscosity, density, sulfur, and asphaltenes content was achieved within the experiment. The influence of catalyst and generated hydrogen on oil quality is one of the additional positive effects of in situ hydrogen generation. The numerical simulation of the experiment was performed for further study of the optimal hydrogen generation conditions. The proposed kinetic model consisted of ISC reactions and hydrogen generation reactions. The primary purpose of this experiment was to validate the principle study of the possibility of in situ hydrogen generation and simulate the processes in the core model physically and numerically.

石油原位燃烧在多孔气藏介质中催化甲烷转化中的应用
甲烷催化转化(CMC)可以在气藏中就地实现。通过这一过程,可以在油气田的多孔介质中生成一种新的环保能源载体——氢。这种方法可以成为一种新的低碳、低成本的制氢方法。为此,必须将催化剂送入储层,并且必须提高储层活性区内的温度。直接提高储层内部温度的有效途径是注入空气和燃烧饱和液态烃。本文研究了油层在原位燃烧(ISC)条件下的CMC过程。采用油的正向湿式ISC加热储层,对甲烷原位产氢进行了数值模拟和物理模拟。本文介绍了在燃烧管内不同空气、蒸汽和甲烷进口流速下,对饱和油岩心压缩模型进行的独特实验结果。实验分为4个部分,分别是油的正态ISC、450℃8.9 MPa的蒸汽甲烷重整(SMR)、550℃8.9 MPa的蒸汽甲烷重整(SMR)和550℃2.3 MPa的蒸汽甲烷重整。这些过程的结合导致产生氢气和甲烷的转化率高达40%(在燃烧阶段)。相比之下,实验中观察到的氢产率较低,可能是由于二次反应。然而,在实验中实现了油粘度、密度、硫和沥青质含量的不可逆降低。催化剂和生成氢对油品质量的影响是原位制氢的另一个积极影响。为进一步研究最佳产氢条件,对实验进行了数值模拟。提出的动力学模型包括ISC反应和产氢反应。本实验的主要目的是验证原位产氢可能性的原理研究,并对核心模型中的过程进行物理和数值模拟。
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来源期刊
Journal of Petroleum Science and Engineering
Journal of Petroleum Science and Engineering 工程技术-地球科学综合
CiteScore
11.30
自引率
0.00%
发文量
1511
审稿时长
13.5 months
期刊介绍: The objective of the Journal of Petroleum Science and Engineering is to bridge the gap between the engineering, the geology and the science of petroleum and natural gas by publishing explicitly written articles intelligible to scientists and engineers working in any field of petroleum engineering, natural gas engineering and petroleum (natural gas) geology. An attempt is made in all issues to balance the subject matter and to appeal to a broad readership. The Journal of Petroleum Science and Engineering covers the fields of petroleum (and natural gas) exploration, production and flow in its broadest possible sense. Topics include: origin and accumulation of petroleum and natural gas; petroleum geochemistry; reservoir engineering; reservoir simulation; rock mechanics; petrophysics; pore-level phenomena; well logging, testing and evaluation; mathematical modelling; enhanced oil and gas recovery; petroleum geology; compaction/diagenesis; petroleum economics; drilling and drilling fluids; thermodynamics and phase behavior; fluid mechanics; multi-phase flow in porous media; production engineering; formation evaluation; exploration methods; CO2 Sequestration in geological formations/sub-surface; management and development of unconventional resources such as heavy oil and bitumen, tight oil and liquid rich shales.
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