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Coal Geology & Exploration

Abstract

CO2 phase transition fracturing (CPTF) is a newly developed technique for coal mine gas control and is characterized by high efficiency, high coal seam permeability, a high gas drainage rate, and outburst elimination. The core of CPTF is reinforced fracturing and the pressure-relief and permeability-enhancement effects of coal seams under high-pressure dynamic loading. Nevertheless, there is a lack of studies on the morphological characteristics and formation mechanisms of newly formed fractures. Current observation and description of the underground fractures on a centimeter-meter scale primarily aim to reveal the fracturing and permeability-enhancement mechanisms of low-permeability coal seams. However, the study of microfractures on a nanometer-micron scale formed by CO2 fracturing can describe the morphology and occurrence patterns of fractures more systematically and comprehensively and reveal the failure mechanisms of coal seams under the action of CPTF. In this study, anthracite samples were subjected to high-pressure CO2 impact (120 MPa) using an independently developed large-scale physical test facility. Based on the observations obtained using a field emission scanning electron microscope (FE-SEM), this study investigated the characteristics, occurrence patterns, and formation mechanisms of micron-scale fractures. The results are as follows: (1) The cleat systems in the fractured coal samples were fully interconnected and formed a multi-scale, complex microfracture network; (2) The coal matrix in the samples was fractured and developed numerous new nanometer-scale microstructures, of which three types of typical microstructures were discovered, namely damage marks, Y-shaped fractures, and foliation structures; (3) The CO2 in the supercritical phase and in the gas phase or in the supercritical phase mixed with the gas phase impacted and fractured the coal samples near the nozzles, and the remote fracturing of the samples was supposed to be primarily induced by shock wave; (4) The microstructures formed and evolved in three steps. First, damage marks formed on the surface of the coal matrix. Then, Y-shaped tensile, dentate branch fractures formed centering around the damage marks. Finally, multiple Y-shaped fractures combined to form a complex microfracture network. The complex reticular fracture system formed by the enhanced fracturing is the underlying reason for the pressure relief, high permeability, high gas drainage rate, and outburst elimination of coal seams.

Keywords

coal, CO2 phase transition fracturing, microstructure, fracture network, gas control, outburst elimination

DOI

10.12363/issn.1001-1986.22.07.0570

Reference

[1] 袁亮. 我国煤矿安全发展战略研究[J]. 中国煤炭,2021,47(6):1−6.

YUAN Liang. Study on the development strategy of coal mine safety in China[J]. China Coal,2021,47(6):1−6.

[2] 李全生. 我国井工煤矿开采技术现状和发展展望[J]. 煤矿开采,2002,7(3):1−5.

LI Quansheng. Present situation of underground coal mining technology and its prospects in China[J]. Coal Mining Technology,2002,7(3):1−5.

[3] 王兆丰,刘军. 我国煤矿瓦斯抽放存在的问题及对策探讨[J]. 煤矿安全,2005,36(3):29−32.

WANG Zhaofeng,LIU Jun. Probe into the problems of methane drainage in China’s coal mines and its countermeasures[J]. Safety in Coal Mines,2005,36(3):29−32.

[4] 谢和平,周宏伟,薛东杰,等. 煤炭深部开采与极限开采深度的研究与思考[J]. 煤炭学报,2012,37(4):535−542.

XIE Heping,ZHOU Hongwei,XUE Dongjie,et al. Research and consideration on deep coal mining and critical mining depth[J]. Journal of China Coal Society,2012,37(4):535−542.

[5] 谢和平,鞠杨,高明忠,等. 煤炭深部原位流态化开采的理论与技术体系[J]. 煤炭学报,2018,43(5):1210−1219.

XIE Heping,JU Yang,GAO Mingzhong,et al. Theories and technologies for in–situ fluidized mining of deep underground coal resources[J]. Journal of China Coal Society,2018,43(5):1210−1219.

[6] 蔡峰,刘泽功. 深部低透气性煤层上向穿层水力压裂强化增透技术[J]. 煤炭学报,2016,41(1):113−119.

CAI Feng,LIU Zegong. Simulation and experimental research on upward cross−seams hydraulic fracturing in deep and low−permeability coal seam[J]. Journal of China Coal Society,2016,41(1):113−119.

[7] 孙炳兴,王兆丰,伍厚荣. 水力压裂增透技术在瓦斯抽采中的应用[J]. 煤炭科学技术,2010,38(11):78−80.

SUN Bingxing,WANG Zhaofeng,WU Hourong. Hydraulic pressurized cracking and permeability improvement technology applied to gas drainage[J]. Coal Science and Technology,2010,38(11):78−80.

[8] 范迎春,王兆丰. 水力冲孔强化增透松软低透突出煤层效果分析[J]. 煤矿安全,2012,43(6):137−140.

FAN Yingchun,WANG Zhaofeng. Effect analysis of strengthening permeability in soft and low permeability outburst coal seam by hydraulic flushing[J]. Safety in Coal Mines,2012,43(6):137−140.

[9] 刘明举,赵文武,刘彦伟,等. 水力冲孔快速消突技术的研究与应用[J]. 煤炭科学技术,2010,38(3):58−61.

LIU Mingju,ZHAO Wenwu,LIU Yanwei,et al. Research and application of hydraulic flushing borehole to quickly eliminate outburst[J]. Coal Science and Technology,2010,38(3):58−61.

[10] 刘彦伟,任培良,夏仕柏,等. 水力冲孔措施的卸压增透效果考察分析[J]. 河南理工大学学报(自然科学版),2009,28(6):695−699.

LIU Yanwei,REN Peiliang,XIA Shibo,et al. Analysis of pressure–relief and permeability improvement effect of hydraulic flushing[J]. Journal of Henan Polytechnic University (Natural Science),2009,28(6):695−699.

[11] WANG Hao,WANG Enyuan,LI Zhonghui,et al. Varying characteristics of electromagnetic radiation from coal failure during hydraulic flushing in coal seam[J]. Arabian Journal of Geosciences,2020,13(14):644.

[12] CHEN Dongdong,HE Wenrui,XIE Shengrong,et al. Increased permeability and coal and gas outburst prevention using hydraulic flushing technology with cross–seam borehole[J]. Journal of Natural Gas Science and Engineering,2020,73:103067.

[13] 曹树刚,李勇,刘延保,等. 深孔控制预裂爆破对煤体微观结构的影响[J]. 岩石力学与工程学报,2009,28(4):673−678.

CAO Shugang,LI Yong,LIU Yanbao,et al. Influence of deep–hole controlled pre–cracking explosion on microstructure of coal[J]. Chinese Journal of Rock Mechanics and Engineering,2009,28(4):673−678.

[14] 胡刚,王晓波,王维维. 低透气性煤层长钻孔爆破增透技术[J]. 黑龙江科技学院学报,2013,23(2):159−162.

HU Gang,WANG Xiaobo,WANG Weiwei. Study on technology of increasing permeability of low gas permeability coal seam by long–drilling explosion[J]. Journal of Heilongjiang Institute of Science and Technology,2013,23(2):159−162.

[15] MA Li,LAI Xingping,ZHANG Jianguo,et al. Blast−casting mechanism and parameter optimization of a benched deep–hole in an opencast coal mine[J]. Shock and Vibration,2020,2020:1−11.

[16] LI He,LIN Baiquan,YANG Wei,et al. Effects of an underlying drainage gallery on coal bed methane capture effectiveness and the mechanical behavior of a gate road[J]. Journal of Natural Gas Science and Engineering,2015,27:616−631.

[17] SZLAZAK N,OBRACAJ D,SWOLKIEN J. Methane drainage from roof strata using an overlying drainage gallery[J]. International Journal of Coal Geology,2014,136:99−115.

[18] 易丽军,俞启香. 突出煤层密集钻孔瓦斯预抽的数值试验[J]. 煤矿安全,2010,41(2):1−4.

YI Lijun,YU Qixiang. Numerical test of gas pre–drainage with dense boreholes in outburst coal seam[J]. Safety in Coal Mines,2010,41(2):1−4.

[19] KARACAN C Ö. Integration of vertical and in–seam horizontal well production analyses with stochastic geostatistical algorithms to estimate pre−mining methane drainage efficiency from coal seams:Blue Creek Seam,Alabama[J]. International Journal of Coal Geology,2013,114:96−113.

[20] 曹运兴,张军胜,田林,等. 低渗煤层定向多簇气相压裂瓦斯治理技术研究与实践[J]. 煤炭学报,2017,42(10):2631−2641.

CAO Yunxing,ZHANG Junsheng,TIAN Lin,et al. Research and application of CO2 gas fracturing for gas control in low permeability coal seams[J]. Journal of China Coal Society,2017,42(10):2631−2641.

[21] 曹运兴,田林,范延昌,等. 低渗煤层CO2气相压裂裂隙圈形态研究[J]. 煤炭科学技术,2018,46(6):46−51.

CAO Yunxing,TIAN Lin,FAN Yanchang,et al. Study on cracking ring form of carbon dioxide gas phase fracturing in low permeability coal seam[J]. Coal Science and Technology,2018,46(6):46−51.

[22] 张宏伟,朱峰,李云鹏,等. 液态CO2致裂技术在冲击地压防治中的应用[J]. 煤炭科学技术,2017,45(12):23−29.

ZHANG Hongwei,ZHU Feng,LI Yunpeng,et al. Application of liquid CO2 fracturing technique in rock burst control[J]. Coal Science and Technology,2017,45(12):23−29.

[23] 程小庆,王兆丰,李豪君. 液态CO2相变致裂强制煤层顶板垮落技术[J]. 煤矿安全,2016,47(6):67−70.

CHENG Xiaoqing,WANG Zhaofeng,LI Haojun. Liquid CO2 phase–transforming fracture technology in forcing coal seam roof collapse[J]. Safety in Coal Mines,2016,47(6):67−70.

[24] 王海东. 突出煤层掘进工作面CO2可控相变致裂防突技术[J]. 煤炭科学技术,2016,44(3):70−74.

WANG Haidong. CO2 controllable phase transition fracturing and outburst prevention technology of gateway driving face in outburst seam[J]. Coal Science and Technology,2016,44(3):70−74.

[25] CAO Yunxing,ZHANG Junsheng,ZHAI Hong,et al. CO2 gas fracturing:A novel reservoir stimulation technology in low permeability gassy coal seams[J]. Fuel,2017,203:197−207.

[26] 杨百舸,张军胜,令狐建设,等. 突出煤层CO2气相压裂高效抽采防突掘进技术[J]. 煤田地质与勘探,2021,49(3):85−94.

YANG Baige,ZHANG Junsheng,LINGHU Jianshe,et al. An advanced CO2 gas−phase fracturing technology for efficient methane drainage,outburst prevention and excavation in outburst coal seam[J]. Coal Geology & Exploration,2021,49(3):85−94.

[27] 赵龙,王兆丰,孙矩正,等. 液态CO2相变致裂增透技术在高瓦斯低透煤层的应用[J]. 煤炭科学技术,2016,44(3):75−79.

ZHAO Long,WANG Zhaofeng,SUN Juzheng,et al. Application of permeability improvement technology with liquid CO2 phase transition fracturing to high gassy and low permeability seam[J]. Coal Science and Technology,2016,44(3):75−79.

[28] 王兆丰,李豪君,陈喜恩,等. 液态CO2相变致裂煤层增透技术布孔方式研究[J]. 中国安全生产科学技术,2015,11(9):11−16.

WANG Zhaofeng,LI Haojun,CHEN Xi’en,et al. Study on hole layout of liquid CO2 phase–transforming fracture technology for permeability improvement of coal seam[J]. Journal of Safety Science and Technology,2015,11(9):11−16.

[29] 张东明,白鑫,尹光志,等. 低渗煤层液态CO2相变射孔破岩及裂隙扩展力学机理[J]. 煤炭学报,2018,43(11):3154−3168.

ZHANG Dongming,BAI Xin,YIN Guangzhi,et al. Mechanism of breaking and fracture expansion of liquid CO2 phase change jet fracturing in low–permeability coal seam[J]. Journal of China Coal Society,2018,43(11):3154−3168.

[30] 张东明,白鑫,尹光志,等. 低渗煤层液态CO2相变定向射孔致裂增透技术及应用[J]. 煤炭学报,2018,43(7):1938−1950.

ZHANG Dongming,BAI Xin,YIN Guangzhi,et al. Research and application on technology of increased permeability by liquid CO2 phase change directional jet fracturing in low–permeability coal seam[J]. Journal of China Coal Society,2018,43(7):1938−1950.

[31] HU Guozhong,HE Wenrui,SUN Miao. Enhancing coal seam gas using liquid CO2 phase–transition blasting with cross–measure borehole[J]. Journal of Natural Gas Science and Engineering,2018,60:164−173.

[32] KANG Jianhong,ZHOU Fubao,QIANG Ziying,et al. Evaluation of gas drainage and coal permeability improvement with liquid CO2 gasification blasting[J]. Advances in Mechanical Engineering,2018,10(4):2072045945.

[33] 陈鹏,孙可明,张宇. 超临界CO2气爆非均质煤体破裂规律模拟研究[J]. 计算力学学报,2021,38(6):770−778.

CHEN Peng,SUN Keming,ZHANG Yu. Simulation of fracturing law of heterogeneous coal caused by supercritical CO2 explosion[J]. Chinese Journal of Computational Mechanics,2021,38(6):770−778.

[34] 孙可明,辛利伟,王婷婷,等. 超临界CO2气爆煤体致裂规律模拟研究[J]. 中国矿业大学学报,2017,46(3):501−506.

SUN Keming,XIN Liwei,WANG Tingting,et al. Simulation research on law of coal fracture caused by supercritical CO2 explosion[J]. Journal of China University of Mining & Technology,2017,46(3):501−506.

[35] 孙可明,辛利伟,吴迪. 超临界CO2气爆煤体致裂机理实验研究[J]. 爆炸与冲击,2018,38(2):302−308.

SUN Keming,XIN Liwei,WU Di. Experimental study on fracture mechanism of coal caused by supercritical CO2 explosion[J]. Explosion and Shock Waves,2018,38(2):302−308.

[36] 刘勇,何岸,魏建平,等. 高压气体射流破煤应力波效应分析[J]. 煤炭学报,2016,41(7):1694−1700.

LIU Yong,HE An,WEI Jianping,et al. Analysis of stress wave effect during coal breakage process by high pressure gas jet[J]. Journal of China Coal Society,2016,41(7):1694−1700.

[37] GE Zhaolong,DENG Kai,ZHOU Zhe,et al. Fracture characteristics of coal jointly impacted by multiple jets[J]. Engineering Fracture Mechanics,2020,235:107171.

[38] 白鑫,张东明,王艳,等. 液态CO2相变射流压力变化及其煤岩致裂规律[J]. 中国矿业大学学报,2020,49(4):661−670.

BAI Xin,ZHANG Dongming,WANG Yan,et al. Pressure variation and coal fracturing law of liquid CO2 phase transition jet[J]. Journal of China University of Mining & Technology,2020,49(4):661−670.

[39] 杜玉昆,庞飞,陈科,等. 超临界二氧化碳喷射破碎页岩试验[J]. 地球科学,2019,44(11):3749−3756.

DU Yukun,PANG Fei,CHEN Ke,et al. Experiment of breaking shale using supercritical carbon dioxide jet[J]. Earth Science,2019,44(11):3749−3756.

[40] 黄飞,卢义玉,汤积仁,等. 超临界二氧化碳射流冲蚀页岩试验研究[J]. 岩石力学与工程学报,2015,34(4):787−794.

HUANG Fei,LU Yiyu,TANG Jiren,et al. Research on erosion of shale impacted by supercritical carbon dioxide jet[J]. Chinese Journal of Rock Mechanics and Engineering,2015,34(4):787−794.

[41] SHANG Zheng,WANG Haifeng,LI Bing,et al. The effect of leakage characteristics of liquid CO2 phase transition on fracturing coal seam:Applications for enhancing coalbed methane recovery[J]. Fuel,2022,308:122044.

[42] 张慧. 煤孔隙的成因类型及其研究[J]. 煤炭学报,2001,26(1):40−44.

ZHANG Hui. Genetical type of pores in coal reservoir and its research significance[J]. Journal of China Coal Society,2001,26(1):40−44.

[43] LAUBACH S E,MARRETT R A,OLSON J E,et al. Characteristics and origins of coal cleat:A review[J]. International Journal of Coal Geology,1998,35(1/2/3/4):175–207.

[44] 杨昌永,常会珍,邵显华,等. 扫描电镜下不同煤体结构煤微孔隙特征研究[J]. 煤炭科学技术,2019,47(12):194−200.

YANG Changyong,CHANG Huizhen,SHAO Xianhua,et al. Study on micro–pore characteristics of structural coal in different coal bodies under scanning electron microscopy[J]. Coal Science and Technology,2019,47(12):194−200.

[45] MOU Pengwei,PAN Jienan,WANG Kai,et al. Influences of hydraulic fracturing on microfractures of high–rank coal under different in–situ stress conditions[J]. Fuel,2021,287:119566.

[46] SU Shanjie,GAO Feng,CAI Chengzheng,et al. Experimental study on coal permeability and cracking characteristics under LN2 freeze–thaw cycles[J]. Journal of Natural Gas Science and Engineering,2020,83:103526.

[47] ZHANG Lei,LU Shuo,ZHANG Cun,et al. Effect of cyclic hot/cold shock treatment on the permeability characteristics of bituminous coal under different temperature gradients[J]. Journal of Natural Gas Science and Engineering,2020,75:103121.

[48] 周科平,柯波,李杰林,等. 液态CO2爆破系统压力动态响应及爆炸能量分析[J]. 爆破,2017,34(3):7−13.

ZHOU Keping,KE Bo,LI Jielin,et al. Pressure dynamic response and explosion energy of liquid carbon dioxide blasting system[J]. Blasting,2017,34(3):7−13.

[49] SHANG Zheng,WANG Haifeng,LI Bing,et al. Experimental investigation of BLEVE in liquid CO2 phase–transition blasting for enhanced coalbed methane recovery[J]. Fuel,2021,292:120283.

[50] 林柏泉,王正,王瑞. 高压气液两相射流裂纹扩展及致裂机理[J]. 中国矿业大学学报,2020,49(1):1−12.

LIN Baiquan,WANG Zheng,WANG Rui. Fracture extension and coal breaking performance by high–pressure gas–liquid jet flow[J]. Journal of China University of Mining & Technology,2020,49(1):1−12.

[51] DING Yang,LYU Yuting,ZHAO Bingjie,et al. Response relationship between loading condition and corrosion fatigue behavior of nickel–aluminum bronze alloy and its crack tip damage mechanism[J]. Materials Characterization,2018,144:356−367.

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