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主办单位:煤炭科学研究总院有限公司、中国煤炭学会学术期刊工作委员会
承压破碎无烟煤气体渗透特性影响因素实验研究
  • Title

    An experimental study of factors influencing gas seepage in confined broken anthracite

  • 作者

    李振余奕睿王红伟冯国瑞何富连王德璋周劲辉柳路妍韩鑫磊

  • Author

    LI Zhen;YU Yirui;WANG Hongwei;FENG Guorui;HE Fulian;WANG Dezhang;ZHOU Jinhui;LIU Luyan;HAN Xinlei

  • 单位

    太原理工大学 安全与应急管理工程学院西安科技大学 西部富油煤绿色低碳开发国家重点实验室太原理工大学 矿业工程学院中国矿业大学(北京) 能源与矿业学院晋能控股集团有限公司中国石油大学(北京) 石油工程学院

  • Organization
    College of Safety and Emergency Management Engineering, Taiyuan University of Technology
    State Key Laboratory of Green and Low-carbon Development of Tar-rich Coal in Western China, Xi’an University of Science and Technology
    College of Mining Technology, Taiyuan University of Technology
    School of Energy and Mining Engineering, China University of Mining and Technology (Beijing)
    Jinneng Holdings Group Co., Ltd.
    College of Petroleum Engineering, China University of Petroleum (Beijing)
  • 摘要
    垮落带破碎煤岩体空隙结构演变直接影响垮落带气体渗透特性,进而影响废弃矿井采空区煤层气运移富集规律。利用自主设计研发的第二代破碎煤岩体压实−渗流−CT扫描试验系统,开展5种粒径破碎无烟煤在不同气体压力、轴向应力及空隙率条件下162组渗透实验。结果表明:(1) 气体在破碎无烟煤中运移时气体压力、流量随时间一直处于动态变化直至达到吸附平衡,流量、压力恒定。(2) 低雷诺数下气体在破碎无烟煤中流动需要拟启动压力梯度,其值处于158.89~1 408.64 Pa/m,并随着轴压增大、空隙率减小而增大。(3) 破碎无烟煤渗透率处于10−12~10−10 m2,且渗透率随气体压力、空隙率增加分别呈现对数、指数函数式增长趋势。(4) 颗粒粒径越大则相同装料空间内破碎煤样初始空隙越大,更易于气体流动,因此相同空隙率时破碎无烟煤渗透率随粒径的增大而增大;不同粒径颗粒渗透率平均变化幅度均随空隙率减小而减小;然而颗粒粒径越大,减小相同空隙率时破碎无烟煤渗透率变化幅度减小越明显。废弃矿井采空区煤层气地面抽采时,地面钻井应优先布设在垮落带破碎煤岩体连同纵向“高位环形裂隙体”共同构成的“U”型高渗煤层气富集区内。
  • Abstract
    The void structure evolution of broken coals in a caving zone directly affects the gas seepage characteristics of the zone, further influencing the gas migration and enrichment patterns in abandoned coal mine goaves. With the second generation of compaction-seepage-CT scanning experimental system for broken coals independently designed and developed, this study performed 162 sets of permeability experiments on broken anthracite samples with five particle size ranges under varying gas pressures, axial stresses, and void fractions. Key findings are as follows: (1) When gas migrated in broken anthracite, its pressure and flow rate kept dynamically changing until the adsorption equilibrium was reached. (2) Under a low Reynolds number, a quasi-starting pressure gradient was required for gas flow in broken anthracite. This gradient ranged between 158.89 and 1408.64 Pa/m, increasing with an increase in axial pressure and a decrease in void fraction. (3) The broken anthracite exhibited permeability ranging from 10−12 to 10−10 m2, increasing logarithmically and exponentially with increasing gas pressure and void fraction, respectively. (4) A larger particle size corresponded to larger initial voids in broken anthracite samples within the same loading space, more conducive to gas flow. Therefore, under the same void fraction, the permeability of broken anthracite increases with particle size. (5) The average changing amplitude of the permeability of particles with varying sizes all decreased with a decrease in the void fraction. For particles with a larger size, the changing amplitude decreased more significantly under the same decrease in the void fraction. To achieve the surface extraction of coalbed methane (CBM) from an abandoned coal mine goaf, ground drilling should be preferably arranged in a U-shaped high-permeability CBM-rich zone composed of broken coals in a caving zone and circular overlying zones at the longwall panel in the vertical direction.
  • 关键词

    瓦斯抽采废弃矿井采空区破碎煤气体压力空隙率粒径渗透率

  • KeyWords

    gas extraction;abandoned coal mine goaf;broken anthracite;gas pressure;void fraction;particle size;permeability

  • 基金项目(Foundation)
    国家杰出青年科学基金项目(51925402);西部富油煤绿色低碳开发国家重点实验室开放课题(SKLCRKF1911);国家自然科学基金青年基金项目(51904198)
  • DOI
  • 引用格式
    李振,余奕睿,王红伟,等. 承压破碎无烟煤气体渗透特性影响因素实验研究[J]. 煤田地质与勘探,2024,52(3):1−13.
  • Citation
    LI Zhen,YU Yirui,WANG Hongwei,et al. An experimental study of factors influencing gas seepage in confined broken anthracite[J]. Coal Geology & Exploration,2024,52(3):1−13.
  • 图表
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    • 破碎煤岩体压实−渗流−CT扫描实验系统
1—气源;2—气体管路;3—抽真空管路;4—一级减压阀;5—二级减压阀;6—真空泵;7—微机控制电液伺服压力机;8—破碎煤岩体压实−渗透−CT扫描装置;9—恒温温控及数据采集系统;10—压力机数据采集计算机

    图(13) / 表(0)

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