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基于分子动力学模拟的非均质页岩孔隙中烃类输运

Hydrocarbon Transportation in Heterogeneous Shale Pores by Molecular Dynamic Simulation.

作者信息

Sun Shuo, Gao Mingyu, Liang Shuang, Liu Yikun

机构信息

Department of Petroleum Engineering, Northeast Petroleum University, Daqing 163318, China.

Key Laboratory of Enhanced Oil Recovery, Northeast Petroleum University, Ministry of Education, Daqing 163318, China.

出版信息

Molecules. 2024 Apr 12;29(8):1763. doi: 10.3390/molecules29081763.

DOI:10.3390/molecules29081763
PMID:38675583
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11052224/
Abstract

Shale oil in China is widely distributed and has enormous resource potential. The pores of shale are at the nanoscale, and traditional research methods encounter difficulty in accurately describing the fluid flow mechanism, which has become a bottleneck restricting the industrial development of shale oil in China. To clarify the distribution and migration laws of fluid microstructure in shale nanopores, we constructed a heterogeneous inorganic composite shale model and explored the fluid behavior in different regions of heterogeneous surfaces. The results revealed the adsorption capacity for alkanes in the quartz region was stronger than that in the illite region. When the aperture was small, solid-liquid interactions dominated; as the aperture increased, the bulk fluid achieved a more uniform and higher flow rate. Under conditions of small aperture/low temperature/low pressure gradient, the quartz region maintained a negative slip boundary. Illite was more hydrophilic than quartz; when the water content was low, water molecules formed a "liquid film" on the illite surface, and the oil flux percentages in the illite and quartz regions were 87% and 99%, respectively. At 50% water content, the adsorbed water in the illite region reached saturation, the quartz region remained unsaturated, and the difference in the oil flux percentage of the two regions decreased. At 70% water content, the adsorbed water in the two regions reached a fully saturated state, and a layered structure of "water-two-phase region-water" was formed in the heterogeneous nanopore. This study is of great significance for understanding the occurrence characteristics and flow mechanism of shale oil within inorganic nanopores.

摘要

中国页岩油分布广泛,资源潜力巨大。页岩孔隙处于纳米尺度,传统研究方法在准确描述流体流动机制方面存在困难,这已成为制约中国页岩油产业发展的瓶颈。为阐明页岩纳米孔隙中流体微观结构的分布和运移规律,我们构建了非均质无机复合页岩模型,并探究了非均质表面不同区域的流体行为。结果表明,石英区域对烷烃的吸附能力强于伊利石区域。当孔径较小时,固液相互作用占主导;随着孔径增大,主体流体流速更均匀且更高。在小孔径/低温/低压梯度条件下,石英区域保持负滑移边界。伊利石比石英更亲水;当含水量较低时,水分子在伊利石表面形成“液膜”,伊利石区域和石英区域的油通量百分比分别为87%和99%。当含水量为50%时,伊利石区域的吸附水达到饱和,石英区域仍不饱和,两区域油通量百分比差异减小。当含水量为70%时,两区域的吸附水均达到完全饱和状态,非均质纳米孔隙中形成“水-两相区-水”的层状结构。本研究对于理解无机纳米孔隙内页岩油的赋存特征和流动机制具有重要意义。

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本文引用的文献

1
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J Phys Chem C Nanomater Interfaces. 2023 May 16;127(20):9452-9462. doi: 10.1021/acs.jpcc.3c00499. eCollection 2023 May 25.
2
Water Bridges in Clay Nanopores: Mechanisms of Formation and Impact on Hydrocarbon Transport.黏土纳米孔中的水桥:形成机制及其对烃类运移的影响
Langmuir. 2020 Jan 28;36(3):723-733. doi: 10.1021/acs.langmuir.9b03244. Epub 2020 Jan 16.
3
Fabrication and verification of a glass-silicon-glass micro-/nanofluidic model for investigating multi-phase flow in shale-like unconventional dual-porosity tight porous media.
用于研究页岩型非常规双孔致密多孔介质中多相流的玻璃-硅-玻璃微纳流控模型的制作与验证。
Lab Chip. 2019 Dec 21;19(24):4071-4082. doi: 10.1039/c9lc00847k. Epub 2019 Nov 8.
4
Enhancement of oil flow in shale nanopores by manipulating friction and viscosity.通过控制摩擦力和粘度提高页岩纳米孔隙中的油流
Phys Chem Chem Phys. 2019 Jun 28;21(24):12777-12786. doi: 10.1039/c9cp01960j. Epub 2019 May 23.
5
The Water-Alkane Interface at Various NaCl Salt Concentrations: A Molecular Dynamics Study of the Readily Available Force Fields.不同 NaCl 盐浓度下水-烷烃界面:易于获得力场的分子动力学研究。
Sci Rep. 2018 Jan 10;8(1):352. doi: 10.1038/s41598-017-18633-y.
6
Role of Interfaces in Elasticity and Failure of Clay-Organic Nanocomposites: Toughening upon Interface Weakening?粘土-有机纳米复合材料弹性和破坏中的界面作用:界面弱化会增韧吗?
Langmuir. 2017 Oct 24;33(42):11457-11466. doi: 10.1021/acs.langmuir.7b01071. Epub 2017 Aug 3.
7
Surface Effect on Oil Transportation in Nanochannel: a Molecular Dynamics Study.纳米通道中表面对输油的影响:一项分子动力学研究
Nanoscale Res Lett. 2017 Dec;12(1):413. doi: 10.1186/s11671-017-2161-2. Epub 2017 Jun 15.
8
Wettability effect on nanoconfined water flow.润湿性对纳米受限水流的影响。
Proc Natl Acad Sci U S A. 2017 Mar 28;114(13):3358-3363. doi: 10.1073/pnas.1612608114. Epub 2017 Mar 13.
9
Activated desorption at heterogeneous interfaces and long-time kinetics of hydrocarbon recovery from nanoporous media.非均相界面的活性解吸与从纳米多孔介质中回收碳氢化合物的长时间动力学。
Nat Commun. 2016 Jun 21;7:11890. doi: 10.1038/ncomms11890.
10
Molecular dynamics simulations of the enhanced recovery of confined methane with carbon dioxide.二氧化碳强化回收受限甲烷的分子动力学模拟
Phys Chem Chem Phys. 2015 Dec 21;17(47):31887-93. doi: 10.1039/c5cp06649b. Epub 2015 Nov 16.