深部软岩巷道开槽卸压等效椭圆模型及模拟分析

大量的工程实践表明,坚硬的岩石在深部也表现出流变特性.针对深部软岩巷道大变性、支护困难的问题,除了采用锚网索主动支护、U型钢或者钢管混凝土等被动支护技术外,开卸压槽是一种控制深部围岩变形的可行方法.本文建立了开槽卸压等效椭圆模型,分析了圆形巷道开槽前后的周边应力场变化规律,揭示了开槽卸压机理.采用FLAC3D模拟了多个开槽参数对直墙半圆拱巷道的影响规律并加以分析,得出了卸压槽开挖最优方案:卸压槽位于直墙上距底板高度为直墙高度为75.0%,深度为巷道宽度的62.5%,高度为直墙高度的15.0%.模拟结果得知基于该方案开槽卸压后,应力明显向深部转移,由于压力导致卸压槽闭合,因此垂直位移明显,而水平位移是原位移的38%,能较好地维护帮部稳定.

杨村煤矿北风井破壁注浆开卸压槽治理井壁

介绍了杨村煤矿北风井井筒采用“横抗纵让”的治理原则,设计采用以卸压槽为主结合“井图加固+套壁+壁后注浆”的综合治理方案。

开槽加固底板控制软岩峒室底鼓的数值分析

底鼓是工作面跨采过后下部软岩硐室变形破坏的主要形式之一。基于峒室围岩条件提出了在底板不对称开卸压槽并用锚杆锚索联合加强支护的治理方案。应用离散元模拟软件UDEC3.0,得到峒室加固前后围岩的垂直应力、底鼓量、位移矢量及弹塑性区范围等的变化。分析结果表明,底鼓量在加固前后分别为640mm、120mm,加固效果明显。对类似条件下控制底鼓具有参考意义。

滑镁岩巷道破坏原因及治理对策分析

滑镁岩松软、破碎,极易受潮膨胀,其中掘进的巷道密集支护钢拱架也常发生顶角、底角及帮梁弯曲,巷道底臌。为了探索该类巷道地压显现的规律及治理对策,应用结构力学简析钢拱架弯曲原因,应用FLAC^(3D)模拟巷道开挖、支护、底板开槽卸压过程及巷道地压变化规律。结果表明:滑镁岩岩体强度低、自承能力弱是其容易失稳、破坏的根本原因,围岩遇潮膨胀是钢拱架等无预应力支护体破坏的直接原因;预应力锚杆、索网喷联合支护并底板开槽卸压是治理该类巷道地压显现的有效方式。

恒源煤矿副井井壁破裂综合治理技术

立井是煤矿的咽喉,井壁的破坏,给煤矿安全生产带来了极大的威胁。在分析井壁的破坏原因基础上,结合矿井生产实际,恒源煤矿副井井壁破裂治理实行抢修加固堵水、井壁开槽卸压两步治理方案,采用围岩加固、注浆堵水、井壁开槽综合治理技术,既减小了对煤矿生产的影响,又为观察研究井壁破裂原因、采取有效措施赢得充裕的时间,目前井筒修复成功,效果显著。

孤岛工作面巷道底鼓机理及控制技术研究

为解决孤岛工作面应力集中区巷道底鼓问题,基于对庞庞塔矿采场巷道围岩特性分析,采用数值模拟方法对巷道底鼓机理和控制技术进行分析,并在井下进行工程试验,在开槽深度为0.5m、1.0 m、1.5 m时,巷道最大底鼓量为342 mm、250 mm、189 mm.试验表明,开槽卸压技术可以有效控制巷道底鼓变形,但开槽深度越大施工难度越大,因此,深度不宜过大。

Field application of non-blasting mechanized mining using high-frequency impact hammer in deep hard rock mine

A non-blasting mechanized mining experiment was carried out with a high-frequency impact hammer,and the daily mining performance was recorded to explore the applicability of the high-frequency impact hammer in deep hard rock mines.Before the field application,the scope of the excavation damage zone was monitored,and rock samples were obtained from the ore body to be mined to carry out a series of laboratory experiments.Field application results show that the overall excavation efficiency reaches 50.6 t/h,and the efficiency of pillar excavation after excavating stress relief slot reaches 158.2 t/h.The results indicate that the non-blasting mechanized mining using high-frequency impact hammer has a good application in deep hard rock mines,and the stress relief slot is conducive to mechanical excavation.In addition,the high-frequency impact hammer also exhibits the advantages of high utilization rate of labor hours,small lumpiness of spalling ore,little dust,and little excavation damage.Finally,according to the field application and laboratory experiment results,a non-blasting mechanized mining method for hard rock mines based on high-frequency impact hammer is proposed.