Influence of Sand Production Damage in Unconsolidated Sandstone Reservoirs on Pore Structure Characteristics and Oil Recovery at the Microscopic Scale

He, Mengqing; Luo, Xiaobing; Yu, Fenglin; Xia, Peng; Teng, Zhihui; Wang, Chen

doi:10.1021/acsomega.2c05357

Cited by 3 publications

(1 citation statement)

References 45 publications

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“…These reservoirs in the Chang 7 Member are distinguished by their multiscale pore-throat architecture, with a widespread development of micro- to nanoscale pores. In these reservoirs, capillary forces are more pronounced than those in conventional ones, thereby enhancing the efficacy of imbibition in oil displacement. − Additionally, the diverse occurrences of fluid storage, the complexity of pore structures, and the high content of clay minerals in shale oil reservoirs make traditional well-logging techniques less effective in assessing key reservoir parameters, such as porosity, permeability, and oil saturation. This has led to an increased focus on research exploring the mechanisms governing the displacement of oil by fracturing fluids through imbibition, with the ultimate goal of optimizing oil recovery rates. − …”

Section: Introductionmentioning

confidence: 99%

Quantitative Analysis of Crude Oil Mobilization in Microscopic Pores during the Spontaneous Imbibition of CO₂-Enhanced Fracturing Fluids in Shale Oil Reservoirs

Li,

Yan,

Wang

et al. 2024

Energy Fuels

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Spontaneous imbibition is integral to various critical phases of shale oil reservoir development, including volume fracturing and water injection, profoundly influencing oil production. Understanding the dynamics of shale imbibition and its influencing factors is essential for optimizing shale oil reservoir recovery rates. This study investigated the behavior of crude oil within microscopic pores during the spontaneous imbibition of fracturing fluids, examining the impacts of shale mineral texture, imbibition techniques, and other relevant variables. Conducted on rock cores from the Chang 7 Member in the Ordos Basin, China, the experiments aimed to decipher the mechanisms by which reservoir physical properties and pore structures influence the spontaneous imbibition of fracturing fluids in shale oil reservoirs. The study also integrated nuclear magnetic resonance (NMR) technology, analyzing alterations in the NMR T 2 spectrum during imbibition. This approach facilitated a detailed study of crude oil mobilization across microscopic pores of varying diameters, enabling a thorough quantitative assessment of oil recovery from diverse pore structures. Experiments were conducted on five core samples using two different formulations of fracturing fluids: the CNI nano variable-viscosity slick water-based fracturing fluid and the EM30 + + guar gum water-based fracturing fluid. The effects of these fracturing fluids on oil displacement were assessed. Findings indicate that smaller pores in shale reservoirs predominantly facilitate crude oil mobilization during the spontaneous imbibition of fracturing fluids with significant activity in the initial stages. Variations in the pore structures of different cores substantially affect the crude oil mobility and displacement rates during the spontaneous imbibition of fracturing fluids. The disparity in pore structures emerges as a principal factor dictating the extent of crude oil mobilization during the spontaneous imbibition of fracturing fluids in shale reservoirs. Moreover, the imbibition capacity is influenced by a range of factors, including rock wettability, reservoir quality, and physical properties.

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Section: Introductionmentioning

confidence: 99%

Quantitative Analysis of Crude Oil Mobilization in Microscopic Pores during the Spontaneous Imbibition of CO₂-Enhanced Fracturing Fluids in Shale Oil Reservoirs

Li,

Yan,

Wang

et al. 2024

Energy Fuels

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Influence of burial conditions on the seepage characteristics of uranium bearing loose sandstone

Jiang,

Jia,

Yang

et al. 2024

Nuclear Engineering and Technology

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Influence of Hydraulic Conditions on Seepage Characteristics of Loose Sandstone

Jia,

Jiang,

et al. 2024

Lithosphere

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To investigate the impact of hydraulic conditions on the seepage characteristics of loose sandstone, this study employed optimized methods to prepare loose sandstone samples. Subsequently, seepage experiments were conducted under different injection pressures, flow rates, and flow volumes. The permeability, porosity, particle size distribution, and other parameters of the rock samples were obtained. By analyzing the response of seepage characteristics to pore and particle size characteristics, the influence of different hydraulic conditions on the seepage characteristics of loose sandstone was explored. The results indicated that improvements in the parameters of hydraulic conditions had different effects on various rock samples. For rock samples with developed seepage channels, increasing the value of each hydraulic condition parameter could expand the channels and discharge particles, and improve permeability. For rock samples with a larger number of small pores, increasing each hydraulic condition parameter caused particles to crack under pressure, drove particles to block holes, and thus reduced permeability. In this experiment, the permeability parameter had a significant positive response to the proportion of pores larger than 0.1 µm and a significant negative response to the proportion of particles smaller than 150 µm.

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Influence of Sand Production Damage in Unconsolidated Sandstone Reservoirs on Pore Structure Characteristics and Oil Recovery at the Microscopic Scale

Cited by 3 publications

References 45 publications

Quantitative Analysis of Crude Oil Mobilization in Microscopic Pores during the Spontaneous Imbibition of CO₂-Enhanced Fracturing Fluids in Shale Oil Reservoirs

Quantitative Analysis of Crude Oil Mobilization in Microscopic Pores during the Spontaneous Imbibition of CO₂-Enhanced Fracturing Fluids in Shale Oil Reservoirs

Influence of burial conditions on the seepage characteristics of uranium bearing loose sandstone

Influence of Hydraulic Conditions on Seepage Characteristics of Loose Sandstone

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Influence of Sand Production Damage in Unconsolidated Sandstone Reservoirs on Pore Structure Characteristics and Oil Recovery at the Microscopic Scale

Cited by 3 publications

References 45 publications

Quantitative Analysis of Crude Oil Mobilization in Microscopic Pores during the Spontaneous Imbibition of CO2-Enhanced Fracturing Fluids in Shale Oil Reservoirs

Quantitative Analysis of Crude Oil Mobilization in Microscopic Pores during the Spontaneous Imbibition of CO2-Enhanced Fracturing Fluids in Shale Oil Reservoirs

Influence of burial conditions on the seepage characteristics of uranium bearing loose sandstone

Influence of Hydraulic Conditions on Seepage Characteristics of Loose Sandstone

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Product

Resources

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Quantitative Analysis of Crude Oil Mobilization in Microscopic Pores during the Spontaneous Imbibition of CO₂-Enhanced Fracturing Fluids in Shale Oil Reservoirs

Quantitative Analysis of Crude Oil Mobilization in Microscopic Pores during the Spontaneous Imbibition of CO₂-Enhanced Fracturing Fluids in Shale Oil Reservoirs