Rock burst induced by roof breakage and its prevention

Based on the research on rock burst phenomenon induced by the breakage of thick and hard roof around roadways and working faces in coal mines, a criterion of rock burst induced by roof breakage （RBRB） was proposed and the model was built. Through the model, a method calculating the varied stresses induced by roof breakage in support objects and coal body was proposed and a unified formula was derived for the calculation of stress increment on support objects and coal body under different breaking forms of roof. Whilst the formula for calculating dynamic load was derived by introducing dynamic index Kd. The formula was verified in Huating Mine by stress measurement. According to the formula for stress increment calculating, the sensitivities of dynamic load parameters were further studied. The results show that the thickness and breaking depth of roof, width of support objeet are the sensitive factors. Based on the discussion of the model, six associated effective methods for rock burst prevention are obtained.

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.

Chaotic Dynamical Features of Rock Breakage Mechanism with Self－controlled Hydro－pick

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Disc-cutter induced rock breakage mechanism for TBM excavation in rock masses with different joint shear strengths

When tunnel boring machines(TBMs)excavate through jointed rock masses,the cutting efficiency is strongly affected by the shear strength of joints,the mechanism of which,however,remains poorly understood.In this study,a series of disc-cutter indentation tests were conducted on granite rock mass specimens with different joint shear strengths.During the indentation,the cracking process was recorded by a digital image correlation(DIC)system.The deformation and strength of specimens,cracking behavior,rock breakage mode and cutting efficiency were quantitatively investigated.In addition,to investigate the combined effects of joint shear strength,orientation and spacing on the rock breakage mechanism,numerical rock mass models were established based on a particle flow code PFC2D.Experimental results reveal that the cracking of primary and secondary cracks changes from the mixed shear-tensile to tensile mode in the initial stage,while the joint shear strength does not affect the cracking mode in the subsequent propagation process.The rock breakage mode is classified to an internal block breakage mode,a cross-joint breakage mode and a cutters-dependent breakage mode.The cross-joint breakage mode is optimal for improving the cutting efficiency.Numerical simulation results reveal that the increase in the joint shear strength changes the internal block breakage mode to cross-joint breakage mode for rock masses of particular ranges of joint orientation and spacing.These findings provide basis for improving the TBM cutting efficiency through jointed rock masses.

结构瞬变影响下采场煤岩静态力学响应的阶变规律

为了明确采场煤岩力学响应的演变规律,以宽沟煤矿W1143长壁综采工作面为工程背景,采用物理相似模拟实验和数值计算相结合的方法,在明确来压前、后覆岩空间结构瞬变特征的基础之上,建立了一种实现坚硬岩层瞬时破断的数值模拟前处理方法,研究了结构瞬变影响下采场煤岩静态力学响应的阶变规律。结果表明:覆岩空间结构是由破裂面以外、采动影响范围以内不同岩性的岩层所组成的空间岩体结构,是其影响范围内的采场煤岩产生不同力学响应的内因。来压期间,由于坚硬岩层的破断具有瞬时性,导致覆岩空间结构发生瞬变,受此影响,采场煤岩的静态力学响应发生阶变,其本质上为一动力学过程。覆岩空间结构瞬变造成采场煤岩的应力场与位移场产生阶变,阶变集中于瞬变区域附近,距离瞬变区域越远,其阶变量越小。

弱化矿岩破碎动力系统的能量转化和时效特性

基于弱化性质矿岩典型的非线性负指数本构关系和灾变特性,分析了灾变和非灾变两种破碎动力学模式下能量转化和时效特性随机构刚度的变化情况。结果表明,低机构刚度诱发的灾变破碎模式会急剧降低破碎动力系统的能量传递效率和破岩时效。从能量利用和破岩功效角度考虑,破碎动力系统不宜采用低机构刚度;给出了机构刚度设计适宜的选用范围。

基于颗粒破碎特性的盐岩集料基层级配组成设计研究

为实现内陆干盐湖区盐岩集料基层级配组成的科学设计,以罗布泊盐岩为研究对象,分析了不同粒径及含卤水率条件下单粒组盐岩集料颗粒破碎演化特征,构建了复杂粒组下盐岩集料级配转移模型,提出了盐岩集料基层级配组成设计方法,验证了盐岩集料基层级配组成设计方法的合理性,并对比了不同级配组成及失水率下盐岩集料的工程性质。结果表明:击实作用下各粒组盐岩集料均发生颗粒破碎,随着击实能量增加,盐岩集料级配趋于稳定,卤水的赋存会降低单粒组盐岩颗粒破碎率。Weibull分布可有效表征盐岩集料破碎颗粒级配分布特征。推荐的盐岩集料基层级配组成设计方法可有效推演盐岩集料基层的级配演化特征并实现考虑卤水影响的级配修正。盐岩集料颗粒间卤水盐分结晶有利于盐岩集料基层强度形成,失水率为75%的盐岩集料无侧限抗压强度可达到4.1 MPa,盐岩集料可用于干盐湖区公路基层填筑工程。

温湿度联合作用下软岩粗粒料三轴剪切力学特性研究

软岩粗粒料具有风化程度高、易破碎等特点,其力学特性易受温湿环境的影响。利用自主研制的温湿控制粗粒料大型三轴仪开展了一系列控制温湿度的软岩粗粒料三轴剪切试验,探究了温湿度对软岩粗粒料剪切强度、剪切变形、颗粒破碎及临界状态的影响规律。研究发现:(1)软岩粗粒料的力学行为受温湿度影响显著,随着温湿度的升高,其峰值剪切强度降低,剪缩变形量增加,颗粒破碎程度增大,p-q空间内的临界状态线向下旋转,同时e-(p/pa)^(ξ)空间内的临界状态线向下平移;(2)温湿度对力学特性的影响在低围压条件下更显著,随着围压的升高,温湿度引起的差异性变小。(3)基于不同温湿度作用下的颗粒破碎等效对应关系,实现了不同温湿工况下颗粒破碎及临界状态试验规律的归一化,为建立统一考虑温湿度影响的本构模型提供思路。

径向不耦合装药爆压消峰作用及其对岩石破裂范围影响

弄清单孔爆破岩石破裂规律是揭示群孔爆破岩石破碎机理的基础。从理论上阐明了单孔爆破岩石破裂机理,采用高能爆轰炸药模型和混凝土损伤模型,分别模拟了空气与水不耦合装药下单孔爆破的应力变化过程、裂纹扩展过程以及不耦合系数为1.0~3.5时岩石粉碎区与裂隙区大小;分析了炮孔壁上爆破压力峰值、粉碎区与裂隙区的大小随不耦合系数的变化规律。研究结果表明:由于不同介质的影响,空气不耦合装药结构对于爆压的削峰作用约是水不耦合装药结构的2倍;当不耦合系数介于1.0~3.5时(药卷直径不变),空气不耦合装药下粉碎区直径介于4.44~1.59倍炮孔直径,裂隙区直径介于22.5~7.62倍炮孔直径;水不耦合装药下粉碎区直径介于4.44~2.74倍炮孔直径,裂隙区直径介于22.5~10.67倍炮孔直径。

土石混合料力学特性和颗粒破碎研究

文中针对土石混合料开展了一系列的室内三轴固结不排水试验。通过对应力-应变关系曲线、强度参数以及颗粒破碎规律等方面进行分析,探讨土石混合料的力学性质与破碎特点。实验数据分析发现,含石量和相对破碎率呈正相关;围压增大,相对破碎率的破碎趋势会逐渐减缓,二者的关系符合Allometricl函数模型。此外,含石量的增加能够提高土石混合料的强度;内摩擦角随含石量的“低-中-高”具有着“慢-快-慢”的增长规律,Boltzmann函数模型能够较好地描述这一规律并具有一定的适用性;土石混合料的黏聚力在含石量较低时较大,含石量较高时黏聚力下降到一定程度后随含石量的增加缓慢增长。

The influence of microwave irradiation on rocks for microwaveassisted underground excavation

Demand is growing for explosive-free rock breakage systems for civil and mining engineering, and space industry applications. This paper highlights the work being undertaken in the Geomechanics Laboratory of Mc Gill University to make a real application of microwave-assisted mechanical rock breakage to fullface tunneling machines and drilling. Comprehensive laboratory tests investigated the effect of microwave radiation on temperature profiles and strength reduction in hard rocks(norite, granite, and basalt)for a range of exposure times and microwave power levels. The heating rate on the surface of the rock specimens linearly decreased with distance between the sample and the microwave antenna, regardless of microwave power level and exposure time. Tensile and uniaxial compressive strengths were reduced with increasing exposure time and power level. Scanning electron micrographs(SEMs) highlighted fracture development in treated basalt. It was concluded that the microwave power level has a strong positive influence on the amount of heat damage induced to the rock surface. Numerical simulations of electric field intensity and wave propagation conducted with COMSOL Multiphysics~ software generated temperature profiles that were in close agreement with experimental results.

Pre-treatment of rocks prior to comminution--A critical review of present practices

It has been an established fact that comminution processes, crushing and grinding, are most energy intensive processes which account for more than half of the total energy consumed in mineral industries.Various alternative pre-treatment methods have been tried by experts around the globe. Although these methods yielded positive results in terms of reduction in energy consumption in crushing and particularly, in grinding operations at laboratory scale, their industrial application still remains an unresolved issue and challenge. Present review paper describes each one of these methods along with outcome of earlier studies and issues that need to be addressed through further rigorous experimental investigation.It also suggests the direction in which future studies can be carried out to meet the primary objective of making comminution processes more energy efficient than today they are.

NUMERICAL SIMULATION STUDY ON ROCK BREAKING MECHANISM AND PROCESS UNDER HIGH PRESSURE WATER JET

The numerical simulation method to study rock breaking process and mechanism under high pressure water jet was developed with the continuous mechanics and the FEM theory. The rock damage model and the damage-coupling model suited to analyze the whole process of water jet breaking rock were established with continuum damage mechanics and micro damage mechanics. The numerical results show the dynamic response of rock under water jet and the evolvement of hydrodynamic characteristic of jet during rock breaking is close to reality, and indicates that the body of rock damage and breakage under the general continual jet occurs within several milliseconds, the main damage form is tensile damage caused by rock unload and jet impact, and the evolvement of rock damage shows a step-change trend. On the whole, the numerical results can agree with experimental conclusions, which manifest that the analytical method is feasible and can be applied to guide the research and application of jet breaking rock theory.

基于连续-离散方法的微波照射下花岗岩力学行为与破裂特征

微波辅助破岩具有绿色、低能耗等优点,是有望实现深部煤炭资源开发中硬岩地层高效掘进的技术手段,其机理引发了工程与学术界的关注。基于花岗岩组分矿物微波吸收升温差异,借助连续介质微波电磁分析及离散元力学模型,实现了微观矿物温度离散赋值,提出了微波照射下花岗岩力学性质的计算分析方法,从温度场分布、力学性质和破坏形态验证了方法的可靠性,揭示了微波照射下花岗岩破裂规律、单/三轴加载条件下的力学行为及破裂机制。计算结果表明:(1)微波照射下,试样出现2个相对低温区域和1个热点区域。在低照射功率(≤2 kW)情况下,试样内部裂纹数量极少;高照射功率(≥3 kW)下,试样内部裂纹以晶粒边界拉伸破坏为主导逐渐发育,并以热点区域为中心向四周延拓形成裂纹网络。(2)对于单轴压缩,试样峰值应力、弹性模量和损伤阈值均随照射功率增加而降低,在高照射功率(≥3 kW)下,力学参数跌落更加明显;当照射功率较高(≥3 kW)时,微波照射后初始裂纹主导了受载试样的裂纹演化,试样呈现沿初始裂纹扩展趋势并出现显著的局部破坏。(3)对于三轴压缩,随照射功率增加,初始围压对试样强度提升效果越发强烈;低照射功率(≤2 kW)下,弹性模量随围压变化不明显,高照射功率(≥3 kW)下,初始围压对弹性模量的提升格外显著;随照射功率增加,围压促进了破碎颗粒的继续承载及应力传递,试样破坏由晶间破坏主导向晶内破坏主导转变,进而引发裂纹网络充分发育,抑制了高功率(≥3 kW)照射产生的局部结构集中破坏。

矿山建设中现代破岩方法综述

随着我国资源开发逐步进入深部开采阶段,深部高硬度岩(矿)石对目前地下工程中岩石破碎提出了新的挑战,各类新型破岩手段应运而生。高压水射流破岩、微波破岩以及液氮低温破岩作为三种热门新型破岩方法已被广泛研究,三种破岩方法的发展历程、工作原理以及适用场景各不相同,但是均具有广阔发展前景。在未来深部坚硬岩石地层环境中,相关研究成果以及理论方法可以为安全、高效、经济及绿色的资源开发提供一定理论基础与技术支撑。

筑坝料变形模量尺寸效应及其外推模型研究

【目的】随着筑坝工程向高坝、大库的发展,筑坝料也向大粒径发展,但配合开展的室内试验因条件规模的限制需以缩尺的形式开展,因而引发了尺寸效应问题。针对堆石坝筑坝料变形模量尺寸效应问题,建立一个根据缩尺筑坝料室内试验值推求原型筑坝料工程实际值的变形模量外推模型。【方法】通过不同径径比下的一系列压缩试验,研究变形模量随尺度参数的变化规律;通过堆石料和砂砾石料颗粒分析试验,研究变形模量随颗粒破碎率的变化规律;根据试验规律推导给出筑坝料变形模量尺寸效应外推模型,并采用该模型对河口村面板坝坝体沉降进行预测。【结果】研究结果表明:堆石料变形模量随径径比增加而增加,砂砾石料变形模量随径径比增加而减小;变形模量随颗粒破碎率增加而减小,颗粒破碎率随径径比增加而减小;新模型使面板坝沉降预测精度提高约6.2%。【结论】根据研究结果可以推知:颗粒破碎是引起两种筑坝石料变形模量尺寸效应变化趋势相反的原因,推导给出的变形模量外推模型可以精准描述两种筑坝石料变形模量的尺寸效应规律,并提高堆石坝沉降预测精度,具有一定的适用性和合理性。为堆石坝筑坝材料尺寸效应研究提供了一个新的思路,提出的模型可以作为堆石坝变形预测的计算工具。

水下钻孔CO_(2)气爆和乳化炸药爆破对比分析

水下爆破作业中飞石、毒气、振动等爆破共生物严重影响水下环境安全,为完成水下炸礁爆破施工任务和不破坏水下生态环境的要求。通过长期的施工经验的思考和总结,提出了水下钻孔CO_(2)气爆代替乳化炸药爆破的施工技术方案。文章通过对比水下破岩CO_(2)气爆与乳化炸药爆破,分析在相同作用效果下,CO_(2)使用量,水击波和地震波数据,以及对鱼类的影响。总结了CO_(2)在水下膨胀破岩作业中的工艺、技术及施工方法,计算出钻孔爆破孔距、排距等相关参数。

开放式微波致裂模拟节理岩体试验及辅助破岩评估

为研究开放式微波作用下节理岩体的破裂特征,并评估微波辅助悬臂掘进机的破岩效率,开展微波致裂模拟节理岩体试验。首先,利用9块尺寸为0.5 m×0.5 m×0.3 m(长×宽×厚)的闪长岩岩样垒成1.5 m×1.5 m×0.3 m(长×宽×厚)的人造节理岩体,以模拟节理间距为0.5 m的岩石开挖面;然后,利用6 kW的工业微波系统及缩径介质填充天线对该节理岩体进行微波照射加热致裂试验,研究不同微波照射点间距(15 cm和20 cm)下岩体的破裂特征,分析节理与照射点间距对微波致裂的影响,测量微波处理后岩体的等效岩石质量指标(RQD)和磨蚀性指数(CAI);最后,基于Bilgin经验模型评估微波照射前后刀盘功率为200 kW的悬臂掘进机的破岩效率和刀具磨损变化。结果表明:1)2种照射点间距下,岩体的等效RQD从100降低到62和50,微波预处理可使悬臂掘进机在该闪长岩岩体中的破岩效率提高170%~280%;2)照射点间距为20 cm时,CAI从4.0减少到3.4,可使刀具损耗降低11%。

深部区域破碎围岩开拓巷道稳定性控制技术研究

针对吉安煤业有限公司5110工作面两巷原“锚网喷+锚索”支护后巷道围岩破碎问题,采用FLAC^(3D)模拟得到锚杆长度2500 mm、锚固长度为锚杆长度1/3、预紧力为锚杆承载力极限值的50%~70%、间排距为700 mm×700 mm时,能最大程度地发挥锚杆的锚固力。同时,增加帮锚索和底板锚索对围岩整体的承载能力。通过监测巷道围岩变形量可知,优化后的支护参数能保证巷道围岩稳定性。

Compaction and seepage characteristics of broken coal and rock masses in coal mining:A review in laboratory tests

Broken coal and rock(BCR)are an important component medium of the caving zone in the goaf(or gob),as well as the main filling material of fault fracture zone and collapse column.The compaction seepage characteristics of BCR directly affect the safe and efficient mining of coal mines.Thus,numerous laboratory studies have focused on the compaction seepage characteristics of BCR.This paper first outlines the engineering problems involved in the BCR during coal mining including the air leakage,the spontaneous combustion,the gas drainage,and the un-derground reservoirs in the goaf.Water inrush related to tectonics such as faults and collapse columns and surface subsidence related to coal gangue filling and mining also involve the compaction seepage characteristics of BCR.Based on the field problems of BCR,many attempts have been made to mimic field environments in laboratory tests.The experimental equipment(cavity size and shape,acoustic emission,CT,etc.)and experimental design for the BCR were firstly reviewed.The main objects of laboratory analysis can be divided into compression tests and seepage test.During the compaction test,the main research focuses on the bearing deformation characteristics(stress-strain curve),pore evolution characteristics,and re-crushing characteristics of BCR.The seepage test mainly uses gas or water as the main medium to study the evolution characteristics of permeability under different compaction stress conditions.In the laboratory tests,factors such as the type of coal and rock mass,particle size,particle shape,water pressure,temperature,and stress path are usually considered.The lateral compression test of BCR can be divided into three stages,including the self-adjustment stage,the broken stage,and the elastic stage or stable stage.At each stage,stress,deformation,porosity,energy,particle size and breakage rate all have their own characteristics.Seepage test regarding the water permeability experiment of BCR is actually belong to variable mass seepage.While the experimental test still focuses on the influence of stress on the pore structure of BCR in terms of gas permeability.Finally,future laboratory tests focus on the BCR related coal mining including scaling up,long term loading and water immersion,mining stress path matching were discussed.