岩土力学 ›› 2021, Vol. 42 ›› Issue (12): 3203-3216.doi: 10.16285/j.rsm.2021.1039

• 基础理论与实验研究 •    下一篇

含瓦斯煤孔裂隙结构精细表征及强度劣化机制

王磊1,刘怀谦1, 2,谢广祥1, 2,袁秋鹏1,陈礼鹏1   

  1. 1. 安徽理工大学 深部煤矿采动响应与灾害防控国家重点实验室,安徽 淮南 232001;2. 中国矿业大学(北京) 能源与矿业学院,北京 100083
  • 收稿日期:2021-07-09 修回日期:2021-08-17 出版日期:2021-12-13 发布日期:2021-12-14
  • 通讯作者: 刘怀谦,男,1992年生,博士研究生,主要从事深部开采动力灾害等方面的研究。E-mail: LHQcumtb@163.com E-mail: leiwang723@126.com
  • 作者简介:王磊,男,1980年生,博士,教授,博士生导师,从事煤矿地下安全开采和深部开采动力灾害等研究工作
  • 基金资助:
    安徽高校协同创新资助项目(No.GXXT-2020-055)

Fine characterization of the pore and fracture structure and strength degradation mechanism of gas bearing coal

WANG Lei1, LIU Huai-qian1, 2, XIE Guang-xiang1, 2, YUAN Qiu-peng1, CHEN Li-peng1   

  1. 1. State Key Laboratory of Mine Response and Disaster Prevention and Control in Deep Coal Mine, Anhui University of Science and Technology, Huainan, Anhui 232001, China; 2. School of Energy and Mining Engineering, China University of Mining and Technology (Beijing), Beijing 100083, China
  • Received:2021-07-09 Revised:2021-08-17 Online:2021-12-13 Published:2021-12-14
  • Supported by:
    This work was supported by the Collaborative Innovation Funding Project of Anhui Universities (GXXT-2020-055).

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摘要: 为探究含瓦斯煤的强度劣化机制,利用自主研制的含瓦斯煤气?固耦合试验系统进行不同初始瓦斯压力下煤体单轴压缩试验,借助SEM、高压压汞、低温液氮吸附法及微焦点CT扫描系统表征含瓦斯煤的孔、裂隙等结构,分别阐述不同瓦斯赋存状态对孔、裂隙的力学和非力学效应,揭示了含瓦斯煤孔、裂隙破坏与宏观强度损失的内在联系。结果表明:煤体平均单轴抗压强度的劣化程度随初始瓦斯压力的升高而升高;多手段联合表征煤体孔隙结构及孔径分布,发现含瓦斯煤裂隙结构发育不明显,孤立孔隙占比较大,两者连通性差,不利于瓦斯渗流;联合表征煤体孔隙结构及孔径分布的方法,可校正微孔及过渡孔或因样品尺寸导致大孔存在“屏蔽效应”和高压阶段煤基质“压缩效应”或孔裂隙破坏带来的误差;吸附态瓦斯分别通过非力学作用和膨胀应力的力学作用,以及游离态瓦斯对煤体的气楔效应致使微元体破裂与失效;构建了基于微细观角度的含瓦斯煤力学性质劣化与宏观强度损失的数学模型,由模型可得,瓦斯作用导致摩尔应力圆圆心向左偏移,摩尔-库仑强度包络线向右偏移,内聚力变小,最终导致煤体宏观强度的损失。

关键词: 含瓦斯煤, 精细表征, 微细观破裂, 宏观劣化, 劣化机制

Abstract: To explore the strength degradation mechanism of gas bearing coal, the uniaxial compression tests were performed on coal under different initial gas pressures by using self-developed gas-solid coupling test system, and the pore and fracture structures of gas bearing coal were characterized by SEM, high-pressure mercury injection, low-temperature liquid nitrogen adsorption and micro-CT scanning system. The mechanical and non-mechanical effects of different gas occurrence states on pores and fractures were described respectively, and the internal relationship between pore and fracture failure and the loss of macroscopic strength of gas bearing coal was revealed. The results show that the degradation degree of average uniaxial compressive strength of coal increases with the increase of initial gas pressure. The pore structure and pore size distribution of coal were characterized by multi-means, and it is found that the development of fracture structure of gas bearing coal is not obvious. The proportion of isolated pores is relatively large, and the connectivity between them is poor, which is not conducive to gas seepage. The method of jointly characterizing the pore structure and pore size distribution of coals can correct the errors caused by "shielding effect" of micropores and transition pores and the errors caused by the "compression effect" of coal matrix or pore and fracture failure caused by the sample size. Adsorbed gas leads to the fracture and failure of micro-elements through non-mechanical action, mechanical action of expansion stress and gas wedge effect of free gas on coal body. The mathematical model of mechanical property deterioration and macro strength loss of gas bearing coal based on the micro view angle was established. From the model, it is found that the action of gas leads to the shift of the center of the Mohr circle to the left, the envelope of Mohr-Coulomb strength to the right, and the cohesion becomes smaller, and finally it leads to the loss of macro strength of coal.

Key words: gas bearing coal, fine characterization, micro-meso fracture, macroscopic degradation, degradation mechanism

中图分类号: 

  • TU452
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