复合煤层钻孔初始瓦斯涌出特性研究

doi:10. 11799/ ce202503019

摘要/Abstract

摘要：

为研究单一性质与复合煤层钻孔初始瓦斯涌出曲线的差异性，采用Comsol Multiphysics模拟钻孔过程中的初始瓦斯涌出曲线，运用煤层模拟装置与连续流量法测定设备监测了三组钻孔初始瓦斯涌出数据，研究了不同性质煤层钻进过程中瓦斯涌出量随钻进深度的变化规律。研究结果表明：破碎带内瓦斯瞬时流速为正常流速的19倍；钻孔瓦斯集中于钻杆前部，且在暴露2s后涌出速度迅速下降；整体钻进距离与钻孔初始瓦斯涌出量曲线存在明显的单调递增函数关系，不过随着时间推移，其增长速率逐渐减缓，这一结论在后续海孜煤矿和威奢煤矿的实验中也得到了验证。采用汇丰煤样对复合煤层（硬煤内部局部存在软煤）进行钻孔初始瓦斯涌出量测定，发现瓦斯曲线异常区域初始瓦斯涌出量的变化趋势与数值模拟相似，异常区域峰值高于正常值2.96倍，这表明该参数对复合煤层具有敏感性。

关键词:

复合煤层 , 初始瓦斯涌出量 , 连续流量法 , 数值模拟

Abstract:

In order to study the difference between the initial gas emission curves of single property and composite coal seam drilling, Comsol Multiphysics was used to simulate the initial gas emission curve of drilling process, and the initial gas emission data of three groups of drilling were monitored by the coal seam simulation device and the continuous flow method. The variation law of gas emission with drilling depth in the drilling process of different coal seams was demonstrated. The research shows that the instantaneous velocity of gas in the fracture zone is 19 times that of the normal, and the gas in the borehole is concentrated in the front of the drill pipe, and the emission rate decreases rapidly after 2 s of exposure. However, there is an obvious monotonically increasing function relationship between the overall drilling distance and the initial gas emission curve of the borehole, and the growth rate gradually slows down with time, which is also verified in the subsequent experiments in Haizi and Weixu coal mines. The initial gas emission of borehole in composite coal seam ( hard coal contains soft coal ) was measured by HSBC coal sample. The change trend of initial gas emission in abnormal area of gas curve is similar to that of numerical simulation, and the peak value of abnormal area is 3.8 times higher than normal value, indicating that the parameter is sensitive to composite coal seam.

中图分类号:

"> TD712+. 5

林华颖, 田世祥, 焦安军, 等.

复合煤层钻孔初始瓦斯涌出特性研究 [J]. 煤炭工程, 2025, 57(3): 143-149.

参考文献

[1] 曹代勇,占文锋,李焕同,等.中国煤矿动力地质灾害的构造背景与风险区带划分[J].煤炭学报,2020,45(07):2376-2388.
CAO Daiyong, ZHAN Wenfeng, LI Huantong, et al. Tectonic setting and risk zoning of dynamic geological disasters in coal mines in China [J]. Journal of China Coal Society, 2020, 45 (07 ): 2376 - 2388.
[2] 乔国栋, 高魁. 淮南煤田逆冲推覆构造对煤与瓦斯突出的影响分析[J]. 矿业安全与环保, 2020, 47 (02 ) : 109 -113.
QIAO Guodong, GAO Kui. Analysis on the influence of thrust nappe structure on coal and gas outburst in Huainan Coalfield [J]. Mining Safety ＆ Environmental Protection, 2020, 47(02 ): 109 - 113.
[3] Jiang CL, Xu LH, Li XW, et.al. Identification model and indicator of outburst-prone coal seams[J]. Rock Mech Rock Eng 2015; 48: 409-415.
[4] Lama RD, Bodziony J. Management of outburst in underground coal mines[J]. Int J Coal Geol 1998; 35: 83-115.
[5] M.S. Civeira, C.G. Ramos, M.L. Oliveira, et al. Nano-mineralogy of suspended sediment during the beginning of coal rejects spill Chemosphere, 145 (2016), pp. 142-147
[6]田世祥,林华颖,马瑞帅, 等.瓦斯涌出量与构造煤关联性预测研究[J].中国安全科学学报,2019,29(10):105-109.
Tian Shixiang, Lin Huaying, Ma Ruishuai, et.al. Prediction of correlation between gas emission and tectonic coal[J]. China Safety Science Journal,2019,29(10):105-109.
[7] 范启炜.工作面钻孔瓦斯涌出初速度特征分析[D]. 抚顺: 煤炭科学研究总院抚顺分院,1985.
Fan Qiwei. Analysis of initial velocity characteristics of gas emission from borehole in working face [D]. Fushun Branch of China Coal Research Institute,1985．
[8]李志强,王司建,刘彦伟,等.基于动扩散系数新扩散模型的构造煤瓦斯扩散机理[J].中国矿业大学学报,2015,44(05):836-842.
LI Zhiqian, WAND Sijian, LIU Yanwei, et al. Mechanism of gas diffusion in tectonic coal based on a diffusion model with dynamic diffusion coefficient [J]. Journal of China University of Minim & Technology,2015,44(05):836-842.
[9]王登科,王洪磊,姚邦华,等.受载原煤中瓦斯的扩散规律[J].煤田地质与勘探,2016,44(03):10-13+20.
Wang Dengke, Wang Honglei, Yao Banhua, et al. Experimental investigation of gas desorption law of loaded raw coal[J]. Coal Geology & Exploration, 2016,44(03):10-13+20.
[10]苗琦.滇东上二叠统煤层煤岩特征及其对瓦斯涌出量的控制[J].煤田地质与勘探,2013,41(04):5-8.
Miao Qi. Petrological characteristics of coal and their control on gas emission of Upper Permian in eastern Yunnan[J]. Coal Geology & Exploration, 2013, 41(04): 5-8.
[11] 张飞燕,韩颖.煤屑瓦斯扩散规律研究[J].煤炭学报,2013,38(09):1589-1596.
ZHANG Feiyan, HAN Ying. Research on the law of gas diffusion from drill cuttings [J]. Journal of China Coal Society, 2013,38(09):1589-1596.
[12]吴立云,王飞,杨玉中.瓦斯参数变化规律的定量化研究[J].采矿与安全工程学报,2014,31(05):824-830.
WU Liyun, WANG Fei, YANG Yuzhong. Quantitative research on gas parameter variation [J]. Journal of Mining ＆ Safety Engineering,2014,31(05):824-830.
[13]卢守青,张永亮,撒占友,等.软硬组合煤体塑性破坏与突出能量失稳判据[J].采矿与安全工程学报,2019,36(03):583-592.
LU Shouqing, ZHANG Yongliang, SA Zhanyou, et al. Criterion of plastic failure and outburst energy instability of soft and hard composite coal [J]. Journal of mining and safety engineering, 2019,36(03):583-592.
[14]韩颖,张飞燕,余伟凡,等.钻孔瓦斯动态涌出规律的实验研究[J].煤炭学报,2011,36(11):1874-1878.
HAN Ying, ZHANG Feiyan, YU Weifan, et al. Experimental study on dynamic law of gas emission from borehole [J]. Journal of China Coal Society, 2011,36(11):1874-1878.
[15]秦跃平,刘鹏,刘伟,等.双重介质煤体钻孔瓦斯双渗流模型及数值解算[J].中国矿业大学学报,2016,45(06):1111-1117.
QIN Yueping, LIU Peng, LIU Wei, et al. Modeling and numerical simulation of borehole methane flow in a dual-porosity, dual-permeability coal seam. Journal of China University of Minim & Technology,2016,45(06):1111-1117.
[16] JunTang, ChaojieWang, YujiaChen, et.al. Determination of critical value of an outburst risk prediction index of working face in a coal roadway based on initial gas emission from a borehole and its application: A case study [J]. Fuel, 2020, 267.
[17] 褚卫江. 低孔隙度岩石细观本构模型及损伤—渗流耦合研究[D]. 南京: 河海大学, 2007.
Chu Weijiang. Study on constitutive model and damage-induced permeability change for low-porosity rock base on micrmechanics[D]. Nan Jing: HoHai University, 2017.
[18]卢亚楠. 煤层瓦斯抽采流固耦合数值模拟与应用研究[D].西安: 西安科技大学,2018.
Lu Yanan. Research on numerical simulation of fluid-solid and field application for coalbed methane recovery[D]. Xi'an: Xi'an University of Science and Technology, 2018