Analyzing the Microscopic Production Characteristics of CO2 Flooding after Water Flooding in Tight Oil Sandstone Reservoirs Utilizing NMR and Microscopic Visualization Apparatus

Xue, Junjie; Gao, Hui; Ma, Zhanguo; Shi, Huaqiang; Li, Xiaoling; Li, Teng; Cheng, Zhilin; Wang, Chen; Li, Pan; Zhang, Nan

doi:10.3390/atmos15040487

Atmosphere

2024

DOI: 10.3390/atmos15040487

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Analyzing the Microscopic Production Characteristics of CO2 Flooding after Water Flooding in Tight Oil Sandstone Reservoirs Utilizing NMR and Microscopic Visualization Apparatus

Junjie Xue,

Hui Gao,

Zhanguo Ma

et al.

Abstract: The microscopic pore structure of tight sandstone reservoirs significantly influences the characteristics of CO2 flooding after water flooding. This research was conducted using various techniques such as casting thin sections, high-pressure mercury injection, scanning electron microscopy, nuclear magnetic resonance (NMR) testing, and a self-designed high-temperature and high-pressure microscopic visualization displacement system. Three types of cores with different pore structures were selected for the floodi… Show more

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Microscale heat and mass transfer characteristics of CO₂ flooding in nanotubes of tight oil reservoirs

Wang

2024

Can J Chem Eng

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The mechanism of heat and mass transfer in tight oil reservoirs after CO2 injection is complex. In this paper, first, a CO2 transfer model within microscale adjacent nanotubes in tight oil reservoirs is established. Then, the typical heat and mass transfer characteristics of microscale CO2 in tight oil reservoirs is analyzed, and the influence of grid density on the calculation results is discussed. Finally, the influence of thermal conductivity of tight oil reservoirs on CO2 physical properties parameters is revealed. Results show that: (a) From the inlet end of the thick nanotube to the outlet of the nanotube, the pressure of CO2 drops from 3.5 to 3.3697 MPa. (b) When the mesh length is equal to 5 nm, the CO2 pressure in the thin nanotube drops from 3.5 to 3.3329 MPa, and the CO2 pressure in the thick nanotube drops from 3.5 to 3.2018 MPa. (c) Organic amines react with CO2 to form salts, which can seal high permeability layers and cracks, but there is a risk of environmental pollution.

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Microscale heat and mass transfer characteristics of CO₂ flooding in nanotubes of tight oil reservoirs

Wang

2024

Can J Chem Eng

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Analyzing the Microscopic Production Characteristics of CO2 Flooding after Water Flooding in Tight Oil Sandstone Reservoirs Utilizing NMR and Microscopic Visualization Apparatus

Cited by 1 publication

References 41 publications

Microscale heat and mass transfer characteristics of CO₂ flooding in nanotubes of tight oil reservoirs

Microscale heat and mass transfer characteristics of CO₂ flooding in nanotubes of tight oil reservoirs

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Analyzing the Microscopic Production Characteristics of CO2 Flooding after Water Flooding in Tight Oil Sandstone Reservoirs Utilizing NMR and Microscopic Visualization Apparatus

Cited by 1 publication

References 41 publications

Microscale heat and mass transfer characteristics of CO2 flooding in nanotubes of tight oil reservoirs

Microscale heat and mass transfer characteristics of CO2 flooding in nanotubes of tight oil reservoirs

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Microscale heat and mass transfer characteristics of CO₂ flooding in nanotubes of tight oil reservoirs

Microscale heat and mass transfer characteristics of CO₂ flooding in nanotubes of tight oil reservoirs