Dynamic Characterization during Gas Initial Desorption of Coal Particles and Its Influence on the Initiation of Coal and Gas Outbursts

Wang, Chaojie; Li, Xiaowei; Xu, Changhang; Chen, Yujia; Tang, Zexiang; Zhang, Chao; Du, Yang; Gao, Xiangyang; Jiang, Cheng‐Lin

doi:10.3390/pr9071101

Cited by 8 publications

(1 citation statement)

References 40 publications

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“…At present, gas pressure measurement methods can be roughly divided into the direct pressure measurement method and indirect pressure measurement method. − The direct pressure measurement method is to drill from the rock lane to the coal seam, to seal the hole with the sealing material, to draw the pressure measuring pipe from the drilling hole, and read out the coal seam gas pressure directly with the pressure gauge, , as shown in Figure . The key to affecting the reliability of the direct method pressure measurement results is the quality of the sealing holes.…”

Section: Introductionmentioning

confidence: 99%

In Situ Volume Recovery Method for Non-Seal Gas Pressure Measurement Technology: A Comparative Study

Hua

Wang

et al. 2022

ACS Omega

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Coal seam gas pressure is one of the basic parameters for coalbed methane resource exploitation and coal mine gas disaster prevention. However, the present coal seam gas pressure measurement technology requires harsh field measurement conditions and a long testing period. In this study, a novel non-seal gas pressure measurement technology is proposed, and this technology is mainly aimed at three different changes before and after the collection of coal samples and realizes the real gas pressure measurement through the compensation of gas leakage, in situ volume recovery of the coal core, and reservoir temperature simulation. The technique not only can measure the original gas pressure of coal seam quickly and accurately but also does not need to seal the measuring hole. This paper focuses on the study of a key factor that affects the accuracy of non-seal gas pressure measurement: the restoration of in situ volume. Based on this, the influence of four different in situ volume recovery methods on the measurement accuracy is compared with the self-developed non-sealing gas pressure measuring system. Experimental results show that the in situ volume of the coal core cannot be completely restored by stress loading. Although the contact injection method can restore the original volume of the coal core, the pressure recovery error is large due to the replacement and displacement of the gas effect of water and the inclusion of the coal body effect of oil. Interestingly, the combination of stress loading and contact oil injection can not only restore the original volume of the coal core but also minimize the pressure recovery error, which is only less than 10%. Finally, based on the abovementioned experimental results, the in situ volume recovery method of non-seal gas pressure measurement technology is improved. Therefore, the research results of this paper provide a scientific basis for the field application of non-seal gas pressure measurement technology.

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Section: Introductionmentioning

confidence: 99%

In Situ Volume Recovery Method for Non-Seal Gas Pressure Measurement Technology: A Comparative Study

Hua

Wang

et al. 2022

ACS Omega

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Study on temperature evolution law of coal containing gas under uniaxial loading process with different loading rates

Cao,

Hao,

Sun

et al. 2024

Env Prog and Sustain Energy

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In order to investigate the evolution law of coal temperature during the gestation process of coal and gas outburst, laboratory experiments and numerical simulation approaches were employed. Infrared thermal radiation experiments on the surface of outburst coal during uniaxial loading and failure of coal were conducted. A coal and gas thermal‐hydromechanical coupling model considering the endothermic effect of desorption was established. Numerical simulation of uniaxial loading of gas‐containing coal was implemented to study the influences of deformation energy, frictional heat, and adsorption/desorption endothermic effects on coal temperature. The results indicate that the temperature of coal samples during the uniaxial loading and failure process generally exhibits a stepwise temperature increase. In the initial stage, the elastic thermal effect leads to a slow and fluctuating rise in the temperature of coal samples. During the yield and plastic deformation stages, frictional heat causes a rapid increase in the temperature of coal samples. With the increase of the loading rate, the increment of the temperature of coal samples gradually decreases and reaches the peak when the loading stress is 70% of the peak stress. According to the numerical calculation results, with the increase of the loading rate, the temperature reduction caused by gas desorption relatively decreases. By comparing the experimental results and numerical simulation results, it is found that the temperature reduction caused by desorption is greater than the temperature increments caused by deformation energy and frictional heat. The desorption endothermic effect and frictional heat effect are the dominant factors controlling the temperature variation of coal during the gestation process of outburst. The research achievements have significant theoretical significance and practical value for revealing the temperature evolution mechanism during the gestation process of coal and gas outburst, predicting coal and gas outburst, and protecting the atmospheric environment.

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Influence of temperature on gas desorption characterization in the whole process from coals and its application analysis on outburst risk prediction

Wang

Chen

et al. 2022

Fuel

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Dynamic Characterization during Gas Initial Desorption of Coal Particles and Its Influence on the Initiation of Coal and Gas Outbursts

Cited by 8 publications

References 40 publications

In Situ Volume Recovery Method for Non-Seal Gas Pressure Measurement Technology: A Comparative Study

In Situ Volume Recovery Method for Non-Seal Gas Pressure Measurement Technology: A Comparative Study

Study on temperature evolution law of coal containing gas under uniaxial loading process with different loading rates

Influence of temperature on gas desorption characterization in the whole process from coals and its application analysis on outburst risk prediction

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