Study on the Technology of Enhancing Permeability by Millisecond Blasting in Sanyuan Coal Mine

Zhao, Dan; Wang, Mingyu; Gao, Xiang

doi:10.1155/2021/8247382

Cited by 2 publications

(1 citation statement)

References 15 publications

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“…Implementing artificial enhanced permeability technologies can effectively improve coal seam gas drainage efficiency, , thoroughly predraining gas from coal seams, and homogenizing gas distribution at the work face, which are fundamental techniques for gas emission homogenization. To achieve this goal, various gas control technologies have been developed and applied globally to address these challenges, including hydraulic fracturing, hydraulic slotting, hydraulic flushing, bottom-up extraction roadway, and deep-hole blasting, − improving gas extraction efficiency to varying degrees. However, research into these technologies has not involved the evaluation of their effects on homogenizing gas emission, which reflects the extraction effect but is more closely tied to the safety and efficiency of production at the work face and is more meaningful for the management of gas in outburst-prone coal seams.…”

Section: Introductionmentioning

confidence: 99%

Research on Pore-Fracture Structure Alteration and Gas Emission Homogenization in an Outburst Coal Seam Induced by CO₂ Gas Fracturing

Yang,

Cao,

Zhang

et al. 2024

ACS Omega

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Considering the alarming frequency of coal mine gas disasters globally, there is an urgent need to develop efficient gas control technologies to ensure mining safety. This study focuses on the problem of high peak gas emission restriction in the process of coal roadway tunneling in outburst coal seams, taking the No. 15 outburst coal seam of the Pingshu Coal Mine as the research object. Based on coal sample testing analysis and the application of CO 2 gas fracturing (CO 2 -Frac) in coal mines, a comprehensive evaluation was conducted on pore-fracture structure alteration and homogenization gas emission effect induced by CO 2 -Frac, providing technical solutions for coal mine safety production. The results are as follows: (1) CO 2 -Frac induces fracture propagation and the development of three types of fracture structures: Tri-Wing Fracture, Damage Markers, and Coal Matrix Fragmentation. (2) Following CO 2 -Frac at 150 MPa, the pore volume and average diameter of pores in the 100−10,000 nm range increased by 128% and 61%, respectively, compared to the pre-CO 2 -Frac state. (3) During the excavation period, continuous monitoring of the airflow for 3 days showed a significant homogenization of gas emission, with a maximum value of 0.450% and a variance value of 0.0031, indicating a reduction of 31% and 68%, respectively. These results reveal several key findings: The pore-fracture structure alteration enhances gas diffusion and permeation, providing high-speed pathways for gas migration, resulting in a substantial increase in gas extraction efficiency. During coal cutting, the modified coal exhibits homogenized gas emission, eliminating the high peak phenomenon and achieving safe and efficient mining. These findings demonstrate that CO 2 -Frac has broad potential in gas emission homogenization for widespread application in coal mines with similar gas geological conditions.

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Section: Introductionmentioning

confidence: 99%

Research on Pore-Fracture Structure Alteration and Gas Emission Homogenization in an Outburst Coal Seam Induced by CO₂ Gas Fracturing

Yang,

Cao,

Zhang

et al. 2024

ACS Omega

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Experimental study on the evolution of three-dimensional fracture structure and enhanced permeability of bituminous coal under high and low temperature conditions

Qiao,

Wang,

Fan

et al. 2024

Preprint

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A systematic study of the three-dimensional reconstructed coal microstructure under low-temperature liquid nitrogen shock and cryogenic-heat shock combined with high-temperature convective heating is of great significance for the improvement of permeability of coal seams by low-temperature media. By combining CT scanning experiments with three-dimensional reconstruction techniques, the pore and fracture structures, their spatial distribution, and connectivity within the coal matrix under single-cryogenic (SC) and cryogenic-heat (CH) treatment conditions were investigated. A pore network model of connection fractures with statistical pore radius, throat radius, and coordination number distribution was constructed, based on the "Volume Fraction module" in Avizo. Finally, the effect was verified by a permeability analyzer. Experimental results indicate that SC treated coal surfaces exhibit partially connected, axially developed fractures. And Coal sample that was subjected to CH treatment showed greater fracture apertures. Significant changes in the fracture volume distribution after different treatments were found by statistical analysis. Specifically, the fraction of fracture volume in CH treated samples between 1010-1011 µm3 decreased from 51.5–5.6%, while the segment from 1011-1012 µm3 jumped from 0–85.47%. Additionally, under different treatment conditions, the overall trend of the number of pores and throats increased and then decreased as the pore radius and throat radius increased, and this trend is more pronounced in coal samples treated with CH. The permeability of gas is largely constrained by the degree of expansion of internal fissures within rocks, the permeability of coal samples decreases with the increase of confining pressure.

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Study on the Technology of Enhancing Permeability by Millisecond Blasting in Sanyuan Coal Mine

Cited by 2 publications

References 15 publications

Research on Pore-Fracture Structure Alteration and Gas Emission Homogenization in an Outburst Coal Seam Induced by CO₂ Gas Fracturing

Research on Pore-Fracture Structure Alteration and Gas Emission Homogenization in an Outburst Coal Seam Induced by CO₂ Gas Fracturing

Experimental study on the evolution of three-dimensional fracture structure and enhanced permeability of bituminous coal under high and low temperature conditions

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Study on the Technology of Enhancing Permeability by Millisecond Blasting in Sanyuan Coal Mine

Cited by 2 publications

References 15 publications

Research on Pore-Fracture Structure Alteration and Gas Emission Homogenization in an Outburst Coal Seam Induced by CO2 Gas Fracturing

Research on Pore-Fracture Structure Alteration and Gas Emission Homogenization in an Outburst Coal Seam Induced by CO2 Gas Fracturing

Experimental study on the evolution of three-dimensional fracture structure and enhanced permeability of bituminous coal under high and low temperature conditions

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Product

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Research on Pore-Fracture Structure Alteration and Gas Emission Homogenization in an Outburst Coal Seam Induced by CO₂ Gas Fracturing

Research on Pore-Fracture Structure Alteration and Gas Emission Homogenization in an Outburst Coal Seam Induced by CO₂ Gas Fracturing