Study on the Spontaneous Combustion Law of Coal Body around a Borehole Induced by Pre-extraction of Coalbed Methane

IF 3.7 3区 化学 Q2 CHEMISTRY, MULTIDISCIPLINARY ACS Omega Pub Date : 2024-09-12 DOI:10.1021/acsomega.4c0267210.1021/acsomega.4c02672
Jun Guo, Xuanchi Zhang*, Yin Liu, Guobin Cai, Hua Liu, Changming Chen and Lei Wang, 
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Abstract

To address the challenges associated with the high gas content, high pressure, and low permeability coefficient in deep coal seams, strategies such as infilling boreholes and increasing the negative pressure of extraction are commonly implemented to alleviate issues related to coalbed methane extraction. However, long-term mining pressure can lead to the development of cracks in the coal seam near the borehole, thereby creating air leakage channels, which could potentially impact the oxygen supply during the extraction process. This leads to secondary disasters such as the spontaneous combustion of coal and gas explosions, considerably impacting the life and health of underground workers. To solve this issue, a thermal–fluid–solid coupling model for the working surface was constructed based on numerical simulation software, taking into account the multimechanism coupling effect of coal seam gas. The laws of coal oxidation and spontaneous combustion induced by coalbed methane extraction around boreholes were studied. The variation laws of the oxygen concentration, coal temperature, and oxidation heating zone around the borehole under different extraction conditions were simulated and analyzed. The findings demonstrate that the negative extraction pressure enables the gas to penetrate the fracture zone of the borehole, leading to an increase in the oxygen consumption rate and coal temperature around the borehole with an increase in negative extraction pressure. The coal gas leakage surrounding the borehole reduces as the sealing depth increases, and both the heating rate of coal and oxygen volume fraction show a downward trend. The fitting relationship between the negative pressure of drainage, depth of sealing, and temperature change in the coal body surrounding the boreholes was identified. It was determined that the negative pressure of 13 kPa for borehole drainage and a sealing depth >18 m are the optimal extraction parameters. The range of the oxidation zone and the position of the boundary line under this parameter were predicted, and the position function of the dangerous area of oxidation heating was defined. The research results have remarkable implications for the coordinated prevention and control of gas and coal spontaneous combustion in coalbed methane predrainage boreholes, as well as for efficient prevention and control of CO in on-site gas extraction boreholes, thus ensuring efficient and safe gas extraction.

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预抽取煤层气诱发钻孔周围煤体自燃规律研究
为了应对深煤层中瓦斯含量高、压力大、渗透系数低等相关挑战,通常会采用充填钻孔、增加抽采负压等策略来缓解煤层气抽采的相关问题。然而,长期的开采压力会导致钻孔附近的煤层出现裂缝,从而形成漏气通道,这有可能影响抽采过程中的氧气供应。这会导致煤炭自燃和瓦斯爆炸等次生灾害,严重影响井下工人的生命健康。为解决这一问题,考虑到煤层瓦斯的多机制耦合效应,基于数值模拟软件构建了工作面热-流-固耦合模型。研究了钻孔周围煤层气抽采诱发煤氧化和自燃的规律。模拟分析了不同抽采条件下井眼周围氧气浓度、煤炭温度和氧化加热区的变化规律。研究结果表明,抽采负压可使瓦斯穿透井眼断裂带,导致井眼周围的耗氧率和煤温随抽采负压的增加而升高。随着封孔深度的增加,井眼周围的煤气泄漏量减少,煤的发热率和氧气体积分数均呈下降趋势。确定了抽放负压、封孔深度和钻孔周围煤体温度变化之间的拟合关系。确定钻孔排水负压为 13 kPa、封孔深度为 18 m 为最佳抽采参数。预测了该参数下氧化区的范围和边界线的位置,并确定了氧化加热危险区的位置函数。该研究成果对煤层气预抽井筒瓦斯和煤炭自燃的协同防控,以及现场瓦斯抽采井筒CO的高效防控,从而确保瓦斯的高效安全抽采具有重要意义。
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来源期刊
ACS Omega
ACS Omega Chemical Engineering-General Chemical Engineering
CiteScore
6.60
自引率
4.90%
发文量
3945
审稿时长
2.4 months
期刊介绍: ACS Omega is an open-access global publication for scientific articles that describe new findings in chemistry and interfacing areas of science, without any perceived evaluation of immediate impact.
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