高级检索

煤与瓦斯突出过程中渗流与煤岩体破坏耦合作用机制

Coupling mechanism of seepage and coal and rock mass destruction during coal and gas outburst

  • 摘要: 针对煤与瓦斯突出诱发机理不清的问题,研究了瓦斯渗流对工作面煤体破坏及煤与瓦斯突出的力学作用机制,分别从煤体渗流试验和土力学2个角度引入瓦斯渗透力这一体积力的概念,明确了瓦斯压力梯度作用在煤体的力学形式。基于弹塑性力学构建了含瓦斯工作面煤体极限平衡方程,进而将渗流与极限平衡区煤体应力进行耦合,从而得到了瓦斯压力作用下煤体拉应力产生以及拉伸破坏的力学原因。从渗透力作用的角度解释了突出孔洞壁层裂破坏特征和层裂体分布规律,揭示突出煤体层裂破坏时瓦斯压力作用的力学本质,并进行了模拟验证。结果表明:含瓦斯煤体受到瓦斯流动产生的渗透力,其大小等于瓦斯压力梯度,从能量的角度来看为单位长度的瓦斯压能损失。渗透力与围岩支承压力共同作用到工作面煤体上,成为破坏煤体的重要诱因。突出前瓦斯流动在新暴露工作面煤壁产生极高的渗透力;渗透力并非均匀地作用在煤壁内,而是集中作用在煤壁暴露面附近小于0.1 m的薄层内,促使煤体采掘方向应力急剧降低甚至成为负值形成拉应力,从而导致该薄层拉伸破坏失稳,形成层裂。煤体内渗透力与应力随时间快速变化,煤壁刚暴露时渗透力是稳定渗流时的6倍以上,相应产生的最大拉应力是稳定渗流时的5倍以上。煤层强度大小与煤体所受拉应力呈现此消彼长的关系,煤层强度越低,由渗流引起的拉应力越大,瓦斯压力的拉伸破坏作用越得以充分发挥,表现为瓦斯为主导的突出和典型的层裂破坏现象。

     

    Abstract: In response to the unclear mechanism of coal and gas outburst, the mechanical action mechanism of gas seepage on coal body damage and coal and gas outburst in working face was studied.The concept of gas permeability as a cohesive force is introduced from the perspectives of coal seepage test and soil mechanics. The mechanical form of gas pressure gradient acting on coal is clarified. Based on elasticity and plasticity mechanics, the limit equilibrium equation of coal body in working face under the action of gas pressure is constructed, and then the seepage flow is coupled with the coal body stress in the limit equilibrium area. The mechanical reasons for the generation of tensile stress and tensile failure of coal under the action of gas pressure are obtained. From the perspective of permeability effect, the failure characteristics of the spalling in the protruding cavity wall and the distribution law of the spalling body are explained, revealing the mechanical nature of gas pressure in outburst coal seam failure. The results show that the permeability force of gas bearing coal body generated by gas flow is equal to the gas pressure gradient. From the energy point of view, the seepage force reflects the gas pressure energy loss per unit length. Permeability and surrounding rock supporting pressure act together on the coal body of the working face, which becomes an important inducement to destroy the coal body. The gas flow before outburst produces extremely high permeability in the coal wall of the newly exposed working face. The seepage force does not act uniformly in the coal wall, but concentrated in the thin layer less than 0.1 m near the exposed face of the coal wall. This action feature of seepage force makes the stress in the mining direction of coal body sharply reduce or even become negative to form tensile stress, which leads to the tensile failure and instability of the thin layer and the formation of spall. Permeability and stress in coal body change significantly with time. When the coal wall is just exposed, the seepage force is more than 6 times that of the stable seepage, and the corresponding maximum tensile stress is more than 5 times that of the stable seepage. With the increase of the exposure time of the coal wall and the progress of seepage, the seepage force is continuously reduced, the tensile stress is also gradually reduced, and the layered fracture body is gradually thickened. In this process, the strength of coal seams shows a trade-off relationship with the tensile stress on the coal body. The lower the coal seam strength, the greater the tensile stress generated, the more the tensile damage of gas pressure is brought into full play, which is characterized by gas dominated outburst and typical spall failure.

     

/

返回文章
返回