煤矿底板采动破坏带深度演化规律研究与现场验证OA
Study on the evolution law of mining-induced floor failure zone depth and its field verification
本文围绕煤矿底板采动破坏带深度展开研究,结合理论分析与现场试验,揭示其演化规律及实际深度.理论层面,将底板采动响应划分为原岩应力平衡、采动应力扰动、底板活化显著、应力恢复平稳四阶段,推导各阶段应力分布模型;基于摩尔库伦强度准则与极限平衡理论,建立底板最大破坏深度塑性公式,并构建破坏深度随工作面推进距离的分段描述函数,阐明破坏深度动态演化机制.现场试验采用钻孔双端封堵漏水量测量法,在大阳煤矿3406回采工作面辅助运输巷布置观测孔A、观测孔B及对比孔A',通过分段封堵、恒压注水与流量监测,量化裂隙发育程度.观测结果显示,对比孔A'不同深度漏水量差异反映裂隙发育梯度,观测孔A、观测孔B底板导水带深度分别为17.6m、16.8 m,验证了理论模型合理性.该研究为矿井底板稳定性评估与突水风险防控提供科学依据.
Research was conducted on the depth of the mining-induced failure zone in coal mine floors.Combined with theoretical analysis and field tests,the evolutionary law and actual depth of the zone were revealed.Theoretically,the mining-induced response of the floor was divided into four stages:in-situ stress equilibrium,mining stress disturbance,significant floor activation,and stress recovery and stabilization.Stress distribution models for each stage were derived.Based on the Mohr-Coulomb strength criterion and limit equilibrium theory,a plastic formula for the maximum failure depth of the floor was established,and a piecewise descriptive function of the failure depth with the advance distance of the working face was constructed,by which the dynamic evolution mechanism of the failure depth was clarified.In field tests,the borehole double-end sealing water leakage measurement method was adopted.Observation Hole A,Observation Hole B,and Contrast Hole A'were arranged in the auxiliary haulage roadway of the working face.The degree of fracture development was quantified through segmented sealing,constant-pressure water injection,and flow rate monitoring.The observation results showed that the difference in water leakage at different depths of Contrast Hole A'reflected the gradient of fracture development.The depths of the floor water-conducting zones at Observation Hole A and Observation Hole B were 17.6 m and 16.8 m,respectively,which verified the rationality of the theoretical model.Scientific basis was provided by this research for the evaluation of mine floor stability and the prevention and control of water inrush risks.
贾勇强
山西兰花科技创业股份有限公司大阳煤矿分公司,山西晋城 048003
矿业与冶金
带压开采底板破坏深度力学模型动力响应底板破坏机理
mining under pressurefloor failure depthmechanical modeldynamic responsefloor failure mechanism
《煤炭与化工》 2026 (5)
24-29,39,7
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