裂隙尺度主控作用下深部采场瓦斯与煤自燃耦合灾害驱动机理及治理技术OA
Driving mechanisms and control technologies for coupled gas and coal spontaneous combustion disasters in deep mines dominated by fracture scale effects
深部资源开采过程中,各类灾害往往呈现群发性、关联性特征,相互作用、叠加影响严重,传统防治手段已难以应对.围绕深部采场灾害防控的核心科学问题,系统梳理了多尺度裂隙在深井采场的表现形式与分布特征;通过引入Knudsen数划分自由分子流、滑移流与连续介质流等不同流态区间,揭示裂隙尺度对层流-湍流转化、摩擦生热及对流换热效率的主导性影响;结合Darcy与Forchheimer渗流模型及对流换热关系式,构建"裂隙尺度-渗透率-流速-热流密度-温度场"的多级传递链,推导层流与湍流条件下的热量传递增强系数,从数学模型角度阐明了裂隙尺度对流态与热质迁移的调控机制.研究表明:在应力场、渗流场、裂隙场、温度场耦合孕育深井灾害的过程中,裂隙场为主导性一级场,其余场均为受其调控的二级场,据此提出"裂隙场是驱动灾害演进的本原,尺度效应是灾害孕育主导控制参量"的新观点.基于此,以深井典型场景下瓦斯与煤自燃耦合灾害为例,提出了主动调控裂隙尺度的灾害防控技术思路,通过液相封堵材料和无机注浆堵漏材料的应用,由渗流速度与氧浓度共同组成的易自燃区域明显缩小,区域内渗流速度明显下降,瓦斯抽采钻孔周围的漏风状况得到改善,在最优注浆位置下复合危险区面积减少 746 m2,采空区流场结构进一步优化.工程实践表明,液相封孔材料、无机注浆堵漏充填材料可调控裂隙场尺度分布,改变流场传质与传热特性,实现对灾害演进路径的主动干预与进程控制.
During deep resource extraction,various disasters often exhibit characteristics of group occurrence and interrelation,with severe interactions and overlapping effects,making traditional prevention and control methods increasingly inadequate.Focusing on the core scientific issues of disaster prevention and control in deep mining stopes,this study systematically analyzes the manifesta-tions and distribution characteristics of multi-scale fractures in deep mine stopes.By introducing the Knudsen number to delineate different flow regimes,such as free molecular flow,slip flow,and continuous medium flow,it reveals the dominant influence of frac-ture scale on the transition from laminar to turbulent flow,frictional heating,and convective heat transfer efficiency.Combining Darcy and Forchheimer seepage models with convective heat transfer relations,a multi-level transmission chain of"fracture scale-permeability-flow velocity-heat flux density-temperature field"is constructed.The heat transfer enhancement coefficients under laminar and turbulent conditions are derived,elucidating the regulatory mechanism of fracture scale on flow regimes and heat-mass transfer from a mathematical modeling perspective.The research shows that during the coupling process of stress field,seepage field,fracture field,and temperature field in the incubation of deep mine disasters,the fracture field serves as the dominant primary field,while the others are secondary fields regulated by it.Based on this,a new perspective is proposed:"the fracture field is the funda-mental driver of disaster evolution,and scale effects are the dominant controlling parameter in disaster incubation".Taking the coupled disaster of gas and coal spontaneous combustion in typical deep mine scenarios as an example,a disaster prevention and control technical approach centered on actively regulating fracture scale is proposed.Through the application of liquid-phase sealing materials and inorganic grouting leakage-plugging materials,the area prone to spontaneous combustion defined by both seepage ve-locity and oxygen concentration is significantly reduced,seepage velocity within the region noticeably decreases,and air leakage around gas extraction boreholes is improved.Under optimal grouting conditions,the area of the composite hazardous zone is re-duced by 746 m2,and the flow field structure in the goaf is further optimized.Engineering practices demonstrate that liquid-phase sealing materials and inorganic grouting leakage-plugging filling materials can regulate the scale distribution of the fracture field,al-ter the mass and heat transfer characteristics of the flow field,and enable active intervention in and control of disaster evolution pathways.
程健维
中国矿业大学 安全工程学院,江苏 徐州 221116
矿业与冶金
裂隙尺度深井采场瓦斯与煤自燃耦合灾害孕育机理灾害防控
fracture scaledeep mine stopecoupled disasters of gas and coal spontaneous combustionincubation mechanismdis-aster prevention and control
《煤矿安全》 2026 (2)
1-14,14
国家自然科学基金资助项目(52474268)
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