Study of the influencing factors of the liquid CO2 phase change fracturing effect in coal seams

Jia, Jinzhang; Wang, Dongming; Li, Bin; Xiuyuan, Tian

doi:10.1371/journal.pone.0254996

Cited by 10 publications

(4 citation statements)

References 15 publications

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“…In order to better apply the liquid CO 2 phase change fracturing technology to the field of low-permeability coal seam permeability enhancement and reinforced anti-outburst field, a field test of liquid CO 2 phase change fracturing for enhanced prepumping coal seam gas through the seam was conducted in the 13th mine of Pingjiang coal mine and through the gas extraction effect after fracturing the coal seam to determine the reasonable placement of liquid CO 2 blasting holes. Jia et al 88 used LS-DYNA software to simulate and analyze the effects of physical parameters of coal seams and borehole diameter on the effect of liquid CO 2 phase change fracturing on coal seams, and the results show that there are positive relationships between the fracturing effect of coal seams and the pressure, modulus of elasticity, and borehole diameter, there are negative relationships with the geopathic stress and compressive strength, and the process is nearly irrelevant to the tensile strength. Hu et al 89 tablished a multiphysical field coupling model and found that the longer the liquid CO 2 phase transition cracking time, the greater the fracturing radius.…”

Section: Current Status Of Research On Anhydrous Coal and Gas Outburs...mentioning

confidence: 99%

Current Status of Research on the Coal and Gas Outburst Control Technology of Hydration and Anhydrous

Zhang,

Wang,

Chen

2023

ACS Omega

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China is one of the countries with the most frequent coal and gas outburst accidents in the world. In the early years of the founding of New China, coal and gas outburst accidents occurred frequently, causing serious casualties, equipment damage, and economic losses. In recent years, some scholars have tried to simulate the coal and gas outburst phenomenon using physical models to study the mechanisms of its occurrence. However, due to the complexity and nonreproducibility of coal and gas outburst disasters, the study of coal and gas outburst mechanisms is still in the hypothesis stage. In order to effectively reduce the risk of coal and gas outburst accidents, coal and gas outburst prevention and control technology have emerged and achieved remarkable results, and the probability of coal and gas outburst accidents has been greatly reduced. Among coal and gas protrusion outburst and control technologies, hydraulic and anhydrous prevention and control technologies are widely used. The purpose of this paper is to briefly explain the mainstream hypothesis of coal and gas outburst, analyze the action principle of hydration and anhydrous control technologies, discuss the current status of research on hydration and anhydrous control technologies, and put forward the problems of current technologies and future development trends.

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Section: Current Status Of Research On Anhydrous Coal and Gas Outburs...mentioning

confidence: 99%

Current Status of Research on the Coal and Gas Outburst Control Technology of Hydration and Anhydrous

Zhang,

Wang,

Chen

2023

ACS Omega

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“…Then they conducted a numerical simulation of CO 2 phase change cracking. The results showed that the influence radius of cracking was 2.55-2.70 m. Jia et al [26], based on the gray correlation analysis method, the effects of different factors on the phase change cracking effect of liquid CO 2 were studied. The results showed that the phase change cracking effect of liquid CO 2 was positively correlated with the changes of gas pressure, elastic modulus, fracture hole diameter, and detonation peak pressure, and this effect was negatively correlated with the changes of in ground stress and compressive strength, and was almost independent of tensile strength.…”

Section: Introductionmentioning

confidence: 99%

Study on prediction of blasting cracking radius of liquid CO2 in coal

Jia

Zhao³

et al. 2023

PLoS ONE

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In this study, we sought to improve the efficiency of coal seam gas extraction, master the characteristics of different factors on the liquid carbon dioxide (CO2) phase change blasting cracking radius, and effectively predict the hole spacing. In this study, we used ANSYS/LS-DYNA numerical simulation software to predict the crack radius of liquid CO2 phase change blasting combined with orthogonal design scheme. The results showed that the primary and secondary factors affecting the fracture radius of liquid CO2 phase change blasting were in ground stress, gas pressure, coal firmness coefficient, and gas content. The fracture radius decreased with the increase of in ground stress and decreased with the increase of gas pressure, coal firmness coefficient, and gas content, which was linear. A prediction model for predicting the cracking radius of liquid CO2 phase change blasting based on four groups of different factors was established. Through the double verification of numerical simulation and field industrial test, the cracking radius of liquid CO2 phase change blasting ranged from 2 m to 2.5 m. The maximum error of numerical simulation was 2.8%, and the maximum error of field industrial test was 5.93%.

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“…Therefore, researchers in the industry have focused on determining the factors that affect blasting cracking and nding methods to improve prediction accuracy. Jia et al [19] studied the in uence of different factors on the phase change cracking effect of liquid CO 2 based on the gray correlation analysis method. The results showed that the gas pressure and ground stress directly affected the blasting cracking effect.…”

Section: Introductionmentioning

confidence: 99%

Prediction of the penetration radius of cumulative blasting

Jia

Zhao

et al. 2023

Preprint

Self Cite

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To improve the efficiency of coal seam gas extraction, determine the influence characteristics of different factors on the penetration effect of cumulative blasting, and effectively predict the hole spacing, in this work, we used ANSYS/LS-DYNA numerical simulation software to establish the penetration model of cumulative blasting. Combined with an orthogonal design scheme, the crack radius prediction of cumulative blasting was studied. The results showed that the primary and secondary order of factors that affected the fracture radius of cumulative blasting was as follows: ground stress > gas pressure > coal firmness coefficient. The penetration effect decreased with increasing ground stress and decreased with an increase in the gas pressure and coal firmness coefficient. According to the pressure index method, an industrial field test was carried out. The gas extraction concentration increased by 73.4% after cumulative blasting, and the effective crack radius of cumulative blasting was approximately 5.5–6 m. The maximum error of the industrial field test was 6.22%, which proved that the crack radius prediction model of cumulative blasting was correct.

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Study of the influencing factors of the liquid CO2 phase change fracturing effect in coal seams

Cited by 10 publications

References 15 publications

Current Status of Research on the Coal and Gas Outburst Control Technology of Hydration and Anhydrous

Current Status of Research on the Coal and Gas Outburst Control Technology of Hydration and Anhydrous

Study on prediction of blasting cracking radius of liquid CO2 in coal

Prediction of the penetration radius of cumulative blasting

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