厚层坚硬岩浆岩下采空区注浆充填试验研究

针对煤层开采形成的厚层坚硬岩浆岩大面积悬顶问题,以海孜煤矿局部岩浆岩侵入体为研究对象,分析了地表岩移和岩浆岩体下离层的发育特征,开展了井下采空区注浆填充试验工作。研究成果表明,海孜煤矿二采区工作面回采后,实测的地表最大沉降量仅为487 mm,远低于无岩浆岩发育区的采动造成的地表沉降量;岩浆岩体未破断,采空区和岩浆岩体之间存在离层空间;通过对垮落带、裂隙带和离层带实施地面钻孔注浆,构建了人工柱体,消除了因厚层坚硬岩浆岩体的大面积悬顶形成的高应力集中现象。

上覆高位岩浆岩下离层空间的演化规律及其预测

针对工作面上覆高位硬厚岩浆岩条件,采用相似材料模拟试验研究了主关键层下离层空间的演化过程与形态特征,分析了离层空间的层位演化与横向扩展规律、覆岩与主关键层的运移规律;通过理论分析揭示了离层空间形成的机理与条件,提出了离层空间演化特征的确定方法,建立了主关键层底部最大离层空间的分析模型与预测方法。研究表明:岩层组合失稳运移形成"月牙"形离层空间,以间歇式跳跃上升至岩浆岩底部,岩浆岩底部存在较大的离层空间,并由"月牙"形逐渐转变为"一字"形,岩浆岩破裂运移导致离层闭合。离层空间在亚关键层及主关键层底部自下而上动态发育与闭合,层位高度及发育范围与推进距离呈正相关性,可采用"多梯形"方法确定其演化过程。覆岩运移经历下位关键层沉降、运移向主关键层底部发展、底部盆地沉降、岩浆岩运移及整体稳定等5个状态,覆岩下沉形态先后呈"V"型、"√"型及"U"型。岩浆岩运移过程分为下部支撑、底部离层扩展、破裂随动、失稳运移及离层闭合稳定等5个阶段。建立了最大离层空间的覆岩结构及弹性基础梁模型,得到其断面积和体积的预测计算式,为高位岩浆岩下安全开采提供了理论依据。

高位硬厚岩层下采场覆岩运动规律及采动应力演化规律

针对工作面上覆巨厚坚硬岩浆岩条件,运用相似模拟试验和数值模拟方法,分别研究了硬厚岩层下采场覆岩运动和采动应力演化规律。研究结果表明,工作面上覆岩浆岩时,覆岩破断的关键阶段分别为直接顶破断、基本顶初次破断、基本顸周期破断、岩浆岩初次破断和岩浆岩周期破断(裂隙沟通地表);硬厚岩浆岩破断前,随着工作面的不断推进,煤体支承压力不断增加;硬厚岩浆岩破断后,采场支承压力要小于破断前。

开采覆岩运动特征及动力响应的数值模拟研究

以地质单元勘查研究报告为背景,应用计算机对某煤矿厚岩浆岩下煤层开采时覆岩移动规律及其动力响应进行了数值模拟分析,得到:①由于岩浆岩这种特殊岩层的存在,使采空区上覆岩层的运动规律发生变异;②岩浆岩存在时,岩体内的应力、变形及位移的变化趋势,揭示了工作面开拓过程中岩体内应力的重新分布过程、工作面支承压力和支架阻力的变异性。

Dynamic disaster control of backfill mining under thick magmatic rock in one side goaf:A case study

In order to explore the control effect of backfill mining on dynamic disasters under special geological mining conditions of overlying thick magmatic rock(TMR),a three-dimensional numerical model of a panel of one side goaf in Yangliu coal mine with double-yield backfill material constitutive model was developed.The simulation results were then compared with field monitoring data.The dynamic disaster control effect of both caving and backfill mining was analyzed in three different aspects,i.e.,displacement field,stress field and energy field.The results show that in comparison to the full caving mining method,the bearing capacity of the goaf after backfilling was enhanced,the backfill mining can effectively reduce the stress and energy accumulated in the coal/rock body,and the backfill mining eliminates the further moving space of TMR and prevents its sudden rupture.Before TMR fracture,the subsidence displacement of TMR was reduced by 65.3%,the front abutment stress of panel decreased by 9.4%on average and the high energy concentration zone around panel was also significantly reduced.Overall,the results of this study provide deeper insights into the control of dynamic disasters by backfill mining in mines.