Stability and control of room mining coal pillars-taking room mining coal pillars of solid backfill recovery as an example

The stability of room mining coal pillars during their secondary mining for recovering coal was analyzed. An analysis was performed for the damage and instability mechanism of coal pillars recovered by the caving mining method. During the damage progression of a single room coal pillar, the shape of the stress distribution in the pillar transformed from the initial stable saddle shape to the final arch-shaped distribution of critical instability. By combining the shapes of stress distribution in the coal pillars with the ultimate strength theory, the safe-stress value of coal pillar was obtained as 11.8 MPa. The mechanism of instability of coal pillar groups recovered by the caving mining method was explained by the domino effect. Since the room coal pillars mined and recovered by the traditional caving mining method were significantly influenced by the secondary mining during recovery, the coal pillars would go through a chain-type instability failure. Because of this limitation, the method of solid backfilling was proposed for mining and recovering room coal pillars, thus changing the transfer mechanism of stress caused by the secondary mining(recovery) of coal pillars. The mechanical model of the stope in the case of backfilling and recovering room coal pillars was built. The peak stress values inside coal pillars varied with the variance of backfilling ratio when the working face was advanced by 150 m. Furthermore, when the critical backfilling ratio was 80.6%, the instability failure of coal pillars would not occur during the solid backfill mining process. By taking Bandingliang Coal Mine as an example, the coal pillars' stability of stope under this backfilling ratio was studied, and a project scheme was designed.

Overlying strata movement of recovering standing pillars with solid backfilling by physical simulation

To analyze the overlying strata movement law of recovering room mining standing pillars with solid backfilling.Physical simulation experiments with sponge and wood as the backfilling simulation material were tested.The results show that:(i) The covering-rock mechanics of the overly strata comes from "two-arch structures + hinged girder + bend beam" to "backfilling material + hinged girder + bent beam" by increasing the fill ratio from 0%to 85%,the beginning of overlying strata movement appears later and the total duration of subsidence velocity increased from zero to the highest value increases.The trend of "single polarization" of the subsidence velocity curves becomes noticeable and the velocity variation trend becomes stable,(ii) The equiponderate aeolian sand was added to improve the anti-pressure ability of the loess,and the corresponding ground processing & transportation system was designed.

某矿山地下开采对地表建(构)筑物的安全影响

为科学预测矿山地下开采对村庄、民房等建(构)筑物的安全影响,防止开采活动造成建(构)筑物的破坏,根据矿山地质和设计资料,利用地表岩移变形理论对主要矿体的地表最大下沉值、影响半径、地表最大倾斜率、地表最大曲率和地表最大水平变形值进行计算,确定理论上的保护等级;采用Flac 3D数值模拟软件对矿山的开采过程进行模拟,分析和总结了地表沉降值及地表变形的变化规律。通过理论公式计算,得出了矿区地表最大倾斜率、曲率和水平变形值分别为0.063 mm/m、1.6×10^(-6) m^(-1)、3.7 mm/m,小于地表建(构)筑物保护等级对应的允许变形值,且地表变形值与所设置地表监测点的位移数据相符。研究结果表明,在按照设计要求进行开采的基础上,矿山开采引起的地表变形不会对地表建(构)筑物安全造成威胁,为矿山建设和安全生产提供了理论依据。

基于FLAC-3D模拟分析某磷矿伪斜房柱嗣后充填采矿方法的稳定性分析

本文运用FLAC-3D数值模拟软件,对磷矿伪斜房柱嗣后充填采矿法的稳定性进行了深入分析。通过模拟不同采矿条件和参数下的矿体变形、应力分布及破坏特征,揭示了该采矿法的稳定性规律,为实际工程提供了理论支撑和实践指导。

房柱交替上升式采矿工艺时空变换力学分析

结合三山岛金矿开采技术条件,设计采用房柱交替上升式充填采矿法回采三山岛金矿深部矿床,并在三山岛金矿直属矿区进行了试验。为获得最佳工艺参数,实现安全回采矿石资源,建立了理论分析模型,通过力学分析,探索了一二步采场时空变换的力学规律,利用MATLAB工具获得了一二步变换的安全步长,为采场支护设计提供了的理论依据。

充填回收房式煤柱围岩变形控制机理

分析垮落法和充填法回收房式煤柱围岩变形特征,得出采用充填法回收煤柱可以更好地控制围岩变形。分析影响回收煤柱围岩稳定性的6个主要因素,得出采空区充采体积比、充填物料抗压特性、工作面液压支架支护强度是可控关键因素,通过优化设备参数、提高采充工艺水平、对充填物料进行初始压实、选择抗压特性高的充填物料、增加液压支架支护强度等方式进行煤柱围岩稳定性控制。

充填回收房式煤柱围岩变形及煤柱承载特征物理模拟研究

为探明风积沙综采固体充填回收房式煤柱采场围岩稳定性特征,采用相似物理模拟方法对比分析了垮落法与充填法回收时的围岩变形及煤柱受力特征,基于相似原理给出了房式开采、垮落法及充填法回收房式煤柱的过程与时间控制方案,确定采用纸张+塑料泡沫+海绵按比例组合并预压缩的方式模拟风积沙充填物料的压缩变形特性。研究发现:(1)相比垮落法,风积沙充填回收煤柱时可大幅减缓覆岩下沉速度,延后及延长覆岩移动周期,避免垮落法回收时因基本顶及上覆坚硬岩层来压剧烈导致的煤柱失稳、煤房垮塌;(2)垮落法与充填法回收时,煤柱的最大承载均出现在超前第1排煤柱上,充填回收可大幅降低超前煤柱的整体承载与应力大小,消除煤柱上的动载现象。

胶结充填采场顶板承载特性及煤柱稳定性分析

为研究连采连充式胶结充填采场顶板承载特性及煤柱稳定性,基于FLAC^(3D)建立数值模型,分析了顶板交替承载特性,研究了顶板主次承载结构的转换规律,揭示了煤柱应力释放及变形规律。基于煤柱两侧约束条件的差异性,建立了煤柱应力分布的力学模型,得到了应力集中系数、临时支护强度、埋深等因素对煤柱极限承载宽度的影响规律。通过煤柱与充填体协同承载的数值模拟,揭示了充填体宽度对煤柱承载特性的影响规律。结果表明:采场顶板承载结构随工作面推进而变换,且在煤柱与充填体协同承载阶段,煤柱为主要承载结构,随煤柱的逐步采出,充填体逐步过渡为主要承载结构;煤柱应力平衡区宽度与临时支护强度呈反比,且与工作面埋深和应力集中系数呈正比,提高临时支护强度,能显著降低临空面破碎区范围,减小极限平衡宽度;增加充填体宽度可保障煤柱稳定。在昊源煤矿中,通过提高充填体强度与充填率,提高充填体对煤柱的约束效应,有效保障了煤柱稳定性,为类似条件下煤柱变形控制提供参考。

充填回收房式煤柱采场煤柱稳定性分析

为了提供充填回收房式煤柱采场围岩稳定性分析的理论依据,采用理论分析和数学推导对充填体-煤柱共同支撑下的围岩力学结构进行了研究,发现煤柱区域弹性地基系数kp、充实率φ、顶板抗弯刚度EI、覆岩载荷q是影响煤柱稳定性的主要控制因素。基于弹性地基梁理论建立了顶板岩梁的挠度方程,提出了煤柱区域及充填体的弹性地基系数计算方法,推导出了充实率对煤柱受力、顶板下沉量、采场应力分布特征的计算方程组,并建立了煤柱稳定性的评价公式。

房柱交替上升式采场结构参数优化研究

房柱交替上升式充填采矿法是一种新的采矿方法。利用ANSYS模拟软件对5种结构参数组合方案进行数值模拟,获得位移、应力、应变等定量指标,并结合实施难易程度、与地质条件的适应性、矿柱回采的相对难易程度、相对生产能力等4个定性指标,通过模糊综合评判,获得最优的采场结构参数组合:矿房宽度10 m,矿柱宽度10 m。对采场结构参数的优化,能够确保矿山安全、高效回采。

固体充填回收房式煤柱塑性区及应力演化特征

为了提供综合机械化固体充填回收房式煤柱采场围岩稳定性控制的理论依据,分析得到了风积沙和黄土混合物料的力学特性和最佳配比,研究了充填物料所受不同初始夯实力、液压支架组对采场煤柱塑性区及应力分布的影响规律。结果表明:随着工作面推进距离的增加,煤柱塑性区最大截面积及煤柱所受应力逐渐增大并趋近于某一定值,且随着充填物料所受初始夯实力的增大,煤柱塑性区最大截面积及煤柱上最大压应力逐渐减小;液压支架可减少工作面周围煤柱的压应力及塑性区发育范围,但影响较小,且随着充填物料所受初始夯实力的增大,液压支架的作用逐渐减弱。结合分析结果和工程实际,设计采空区充填致密度临界值为1 684.70 kg/m^3。

张赵煤矿尾砂膏体充填技术研究与应用

为释放村庄下压煤,提高资源回采率,减少开采引发的环境破坏,根据张赵煤矿生产地质条件,提出利用尾砂膏体充填技术对102采区进行跳采充填,采5m,留煤柱15m,待充填后再对15m煤柱进行分段回收充填。介绍了尾砂膏体充填过程中密封墙的砌筑、充填管路铺设、管路清洗和制浆工作等。充填后实测分析表明,采区上方地表下沉系数为0.10,最大下沉量为240 mm,最大水平变形为0.8 mm/m,最大倾斜值为2.2mm/m,充填效果较好。

三山岛金矿深部采场的充填与支护技术

分析了三山岛金矿深部采场充填存在的问题,提出采用分次充填、分区充填、多点下料及强制充填等方法解决充填接顶率低的问题。根据理论计算,对深部矿区一步采采场及二步采采场支护设计参数进行优化,以确保采场回采安全。