Analysis of stability of coal pillars with multi-coal seam strip mining

Strip mining is one of the efficient measures to control surface subsidence and mining damage. However, the researches on the laws of the geological mining factors to upper and lower pillar's stability are still deficient in multi-coal seam strip mining at present. Based on the three dimension fast Lagrangian analysis of continua (short for FLAC3D) numerical simulation software, the laws of the stress increasing coefficient on the coal pillar and its stability were systematically studied for different depths, different mining widths, different interlayer spacings, different mining thicknesses, different properties of interstratified rock and the spacial relations of the upper and lower pillars in vertical alignment in multi-coal seam strip mining. The function relation between the stress increasing coefficient of upper and lower pillars with the mining depth, mining widths, interlayer spacing, mining thickness, property of interstratified rock and the spatial relationship were obtained.

Characteristics of stress distribution in floor strata and control of roadway stability under coal pillars

Given the difficulties encountered in roadway support under coal pillars,we studied the characteristics of stress distribution and their effect on roadway stability,using theoretical analysis and numerical simulation.The results show that,under a coal pillar,vertical stress in a floor stratum increases while horizontal stress decreases.We conclude that the increased difference between vertical and horizontal stress is an important reason for deformation of the surrounding rock and failures of roadways under coal pillars.Based on this,we propose control technologies of the surrounding rock of a roadway under a coal pillar,such as high strength and high pre-stressed bolt support,cable reinforcement support single hydraulic prop with beam support and reinforcement by grouting of the surrounding rock,which have been successfully applied in a stability control project of a roadway under a coal pillar.

Suitable layout of gate roads related to slice mining in an ultra-thick unstable coal seam

We determi：ned a suitable gate road layout in slice mining in an ultra-thick unstable coal seam, using theoretical anallysis and numerical calculations. Based on plasticity theory in terms of limiting equilibrium, the width of chain pillar in the upper slice was calculated to be 18 m. The stress distribution in the chain pillar after the upper slice was mined out was described with numerical simulation. The extent of the effect of stress on the upper chain pillar on the lower solid coal was obtained on the basis of an elastic solution of a distributed force loaded on a half-plane. Three layout designs for lower gate roads were pro- posed and a stability factor was introduced to analyze the stability of the lower pillar with numerical calculation. Gate road translation was determined as the most suitable layout method, which maximizes the extraction rate on the basis of the pillar stability.

Numerical Study on an Applicable Underground Mining Method for Soft Extra-Thick Coal Seams in Thailand

The EGAT Mae Moh Mine is the largest open pit lignite mine in Thailand and it produces lignite about 16 million tons annually. In the near future, the pit limit of the mine will be reached and underground mine will then be developed through the open pit in the depth of 400 - 600 m from the surface. However, due to the challenges for underground mining such as poor geological conditions, extra thickness (20 - 30 m) of coal seams, and weak mechanical properties of coal seams and the surrounding rock, the success possibility of underground mining and an applicable underground mining method is being investigated at the present. The paper discusses the applicability of multi-slice bord-and-pillar method for the soft extra thick coal seams in the Mae Moh mine by means of numerical analyses using the 3D finite difference code “FLAC3D”.

Evaluation of roof cutting by directionally single cracking technique in automatic roadway formation for thick coal seam mining

Automatic roadway formation by roof cutting is a sustainable nonpillar mining method that has the potential to increase coal recovery,reduce roadway excavation and improve mining safety.In this method,roof cutting is the key process for stress relief,which significantly affects the stability of the formed roadway.This paper presents a directionally single cracking(DSC)technique for roof cutting with considerations of rock properties.The mechanism of the DSC technique was investi-gated by explicit finite element analyses.The DSC technique and roof cutting parameters were evaluated by discrete element simulation and field experiment.On this basis,the optimized DSC technique was tested in the field.The results indicate that the DSC technique could effectively control the blast-induced stress distribution and crack propagation in the roof rock,thus,achieve directionally single cracking on the roadway roof.The DsC technique for roof cutting with optimized parameters could effectively reduce the deformation and improve the stability of the formed roadway.Field engineering application verified the feasibility and effectiveness of the evaluated DSC technique for roof cutting.

Theories and techniques of coal bed methane control in China

Coal bed methane control with low permeability is a hot issue at present. The current status of coal bed methane control in China is introduced. The government-support policies on coal bed methane control are presented. This paper proposes the theories of methane control in depressurized mining, including methane extraction in depressurized mining, simultaneous mining technique of coal and methane without coal pillar, and circular overlying zone for high-efficiency methane extraction in coal seams with low permeability. The techniques of methane control and related instruments and equipments in China are introduced. On this basis, the problems related to coal bed methane control are addressed and further studies are pointed out.

松软厚煤层区段煤柱剪切滑块运动机理及协同控制技术

松软厚煤层区段煤柱高、煤壁暴露面积大,加之煤质松软、裂隙发育,强采动作用下极易造成煤柱失稳,巷道维护难度极大。以山西伏岩煤业3号煤层开采为工程背景,基于剪切滑块理论,探究采掘扰动下煤柱变形破坏机理,求解煤柱剪切滑块运动范围及应力分布规律,揭示煤柱侧帮剪切滑块运动机理,提出煤柱稳定性协同控制对策并在现场进行工程实践验证。结果表明:①采用极限平衡理论与叠加理论,确定了煤柱剪切滑块运动范围及煤柱垂直应力分布规律,阐明煤柱剪切滑块安全系数分布规律:0~1.26 m深度,煤柱上部安全系数较小;在1.26~3.95 m处,煤柱中线部分大面积安全系数较小,易受顶板来压破坏。②提出了1种以“注浆加固—锚索强化—切顶卸压”为主体的区段煤柱协同控制技术,煤柱侧裂隙较无支护条件及原支护条件分别减少62.89%和46.26%,巷道围岩完整性大幅提高,形成了强承载结构,有效控制了煤柱变形及底臌。③根据松软厚煤层区段煤柱条件,合理确定了协同控制设计参数,并对煤柱防控效果进行试验监测评估。现场试验结果表明,煤柱裂隙得到充分填充,注浆后煤体强度提高63%以上;巷道位移、锚杆索受力、离层等均在可控范围,表明协同控制技术明显提高了煤柱承载力,回采巷道围岩变形得到有效控制,为工作面安全高效开采提供了空间保障。

深埋倾斜特厚煤层窄煤柱护巷机理与围岩控制

我国中东部地区采深大、巷道变形和冲击风险大,窄煤柱沿空掘巷技术可改善巷道围岩环境。为掌握窄煤柱护巷机理并形成针对性围岩控制技术体系,以800 m埋深倾斜特厚煤层3 m窄煤柱沿空掘巷为背景,开展了理论分析、现场实测及数值模拟研究,结果表明:①该巷围岩破碎程度及变形煤柱侧比实体煤侧严重,煤柱破碎程度及变形采空区侧比巷道侧大,尽管埋深大,但已稳定采空区承担较大覆岩载荷,高应力已充分向深部岩体分流;②巷道变形非对称,实体煤侧顶板下沉量比煤柱侧大,巷帮以浅部变形为主,煤柱帮上部和实体煤帮中部变形较大;③采空区是掘巷卸荷后主要的形变通道,利于形变能向采空区缓释、降低冲击风险;④卸压区形状由掘巷前三角形扩展为掘巷后平行四边形,掘巷后应力集中区转移至实体煤帮右上方实体煤岩体中;⑤窄煤柱一次和二次剪切破坏的交界面及掘巷右上方实体高应力区为围岩关键控制区,据此提出基于煤柱多重塑性破坏区发育规律的煤柱加固和高应力区精准卸压联合的围岩控制技术体系。研究可为邻近工作面以及其他类似深埋倾斜特厚煤层开采提供理论支撑和科学依据。

特厚煤层小煤柱沿空掘巷支护技术研究

小煤柱沿空掘巷过程中易出现巷道围岩变形大、局部鼓出等现象,针对这一问题,采用理论分析、数值模拟、工程类比的方法,对巷道基本顶破断方式进行了判断,并采用数值模拟分析不同宽度下煤柱的应力及位移变化规律,初步确定了煤柱留设宽度为8 m;对比邻近矿井的沿空掘巷案例,采用工程类比法最终确定了煤柱宽度,并对巷道支护方案进行设计,现场应用效果良好。

极近距离煤层下伏回采巷道分区支护技术及应用

针对极近距离煤层下伏回采巷道距上覆采空区间距不等的特点,采用统一性的支护方案易造成支护稀疏或支护过度的问题。基于有效锚固层“叠加梁”理论,根据极近距离煤层层间距变化将实验地段风巷划分为“大于6.0m、4.0~6.0m和小于4.0m”三个区域,针对性提出极近距离煤层回采巷道顶板分区域支护方案,通过数值模拟计算论证了方案的可行性,并在任楼煤矿工作面回采巷道进行工业性试验。结果表明:不同区域采用针对性支护后围岩均较稳定,巷道围岩变形得到了合理的控制,巷道总体变形量较小,分区域式支护技术有效控制下伏巷道围岩变形,保证了矿井安全生产,降低了企业成本。

特厚煤层沿空掘巷围岩支卸协同控制技术

针对特厚煤层小煤柱沿空掘巷大范围塑性全煤巷道锚网索的支护难题,以塔山煤矿8204-2小煤柱工作面为工程背景,采用现场实测、理论分析等方法,揭示了锚杆、锚索对沿空大范围塑性全煤巷道的支护机理。锚杆支护主要作用于浅部二次破碎区煤体,形成浅部连续承载结构;锚索主要作用于深部处于三向受力状态的稳定煤体,形成更大范围的连续稳定承载结构;进一步明确了锚杆、锚索有效长度的计算方法,形成了以高预紧力、高强“锚-网-索”支护为基础,以坚硬顶板井下磨料水射流切顶卸压、巷帮大直径钻孔卸压、底板卸压槽卸压为辅的“支卸协同”小煤柱沿空巷道围岩控制技术体系。工程应用结果表明,试验巷道围岩最大变形量小于700 mm,能够满足使用要求。

煤层群下行开采底板应力演化规律与合理巷道错距研究

为解决近距离煤层开采遗留煤柱下伏回采巷道合理布置工程问题,采用理论分析、数值模拟和现场实测相结合的方法,基于半无限平面体理论建立遗留煤柱底板岩层应力分布力学模型,系统研究了遗留煤柱下伏底板岩层应力分布特征及减压区相对位置关系,提出遗留煤柱非均布载荷影响的底板水平/垂向距离判别方法,揭示了遗留煤柱水平/垂向间距对下伏煤层回采巷道应力变化率的影响程度。结果表明:垂直应力集中是导致下伏巷道失稳的主控因素,以垂直应力变化量0.2γH作为评判应力影响程度的临界指标,探究了不同因素影响下的应力扰动程度,随着遗留煤柱尺寸、煤层间距、埋深与岩层垮落角逐渐减小,底板岩层应力影响深度呈递减趋势;随着水平错距增大,巷道围岩垂直应力值、应力变化率差值不断减小,界定两者数值低于0.2γH与0.01时,围岩达到可控稳定状态;现场试验21320回风巷采用外错式25 m进行实测验证,优化布置后巷道顶板相对位移量控制在45 mm以内,服务期间巷道围岩工况稳定,验证了所得安全错距的合理性。

近距离煤层底板应力分布规律及巷道布置研究

为探究上煤层遗留煤柱对底板的应力影响及下煤层回采巷道的合理布置,以唐山沟煤矿为研究对象,运用理论分析和数值模拟等方法并综合多种影响因素构建了上煤层遗留煤柱与铰接岩块的协同承载结构模型和底板应力传递计算模型,对上煤层遗留煤柱下底板应力及影响因素展开研究。结果表明:上煤层遗留煤柱对底板的应力影响以垂直应力为主,影响程度随底板深度的增加而降低;遗留煤柱下底板应力增高区呈椭球形,对底板应力增高区的影响因素展开分析,得到了不同因素对应力增高区范围影响的量化关系,其中煤柱峰值应力对底板应力增高区分布起决定性作用;根据底板应力分布特征并结合理论计算及数值模拟结果,确定唐山沟煤矿8煤遗留煤柱与11^(-1)煤回采巷道合理错距值应为20~25 m。该研究揭示了上煤层遗留煤柱下底板应力传递机理,明确了底板应力增高区的分布及影响因素,并得到了巷道-煤柱合理错距值的确定方法,可为下煤层回采巷道的合理布置提供理论依据。

浅埋近距离煤层过平行煤柱开采强矿压机理研究

为了揭示浅埋近距离煤层工作面过平行煤柱开采动载传递特征及强矿压机理,以榆家梁煤矿43207工作面为工程背景,采用现场实测、物理模拟、理论分析相结合的方法,研究了煤柱覆岩“倒梯形”结构随下部间隔岩层的运动及其载荷传递特征,分析了超前支承压力和支架载荷的转化规律,建立了“煤柱-间隔岩层台阶岩梁”耦合结构力学模型,得出了强矿压瞬间和顶板切落稳定后的支架载荷计算公式。研究结果表明:煤柱覆岩“倒梯形”结构的集中应力和载荷主要集中于煤柱后段,后段集中载荷是导致工作面过煤柱强矿压的根源;工作面进煤柱初期,煤柱应力表现为双峰;临近出煤柱时,应力集中为单峰,位于煤柱后段。工作面出煤柱4 m后,煤柱后区的超前支承应力系数达到峰值6.00,间隔层开始产生超前裂隙;出煤柱5 m时发生强矿压,煤柱应力下降43%。强矿压期间,煤柱应力传递至煤柱下7 m层位(间隔岩层关键层中部)下降了39%,表明顶板结构承担了相当大的载荷。基于间隔岩层台阶岩梁结构的理论计算,得出强矿压瞬间的支架载荷计算公式,按照煤柱平均应力计算得出支架载荷为22.9 MN/架,按照强矿压时刻煤柱后段应力计算得出支架载荷为24.1 MN/架;煤柱传递至支架的载荷仅为煤柱总载荷的12%~18%,仍超过现场支架额定工作阻力9.2 MN/架。因此,为防止压架,支架额定工作阻力需达到15 MN/架,或者对煤柱及间隔岩层结构进行处理,以保证安全开采。研究结果可为类似条件工作面过平行煤柱开采提供参考。

以煤层倾向为参考方向的锐角优化垂线法煤柱设计方法

垂线法广泛应用于我国矿区地表建(构)筑物的保护煤柱的设计,但其原理中存在走向方向不明确导致计算时需人工干预和小角值拐角处保护煤柱过估等问题。针对村庄尺度的建筑物群,提出应按位置给出不同的开采参数和松散层参数;用煤层倾向作为垂线法的参考方向,代替指向不明确的走向,实现垂线计算公式选择、垂线长度计算的自动化;提出锐角优化算法,解决煤柱角点角值较小时出现的煤柱留设尺寸过大问题。基于上述优化,通过MATLAB编程实现煤柱自动化计算,并一定程度上减小了煤柱的尺寸。优化后的垂线法能够更好地应用于矿山保护煤柱设计。

深部特厚煤层综放沿空掘巷煤柱优化及巷道支护

为研究深部大采高综放工作面窄煤柱沿空掘巷巷道矿压控制问题,以国能宁煤集团枣泉煤矿2^(-2)特厚煤层130203大采高综放工作面回风巷道为背景,基于实用矿山压力理论,建立了巷道围岩内、外应力场动态结构力学模型,运用理论计算和数值计算针对不同尺寸煤柱煤体应力对比分析,将原留设15 m护巷煤柱缩小至5 m进行了煤柱优化。结果表明:在稳定的内应力场掘巷有利于巷道的稳定性,避免了顶板事故及冲击地压相关灾害的发生,现场5 m小煤柱护巷工程应用中,130203回风巷道小煤柱侧变形量为1050 mm,实体煤帮变形量为400 mm,两帮呈现不对称性变形,底板局部底鼓量为1400 mm;深部特厚煤层综放开采沿空掘巷采用5 m小煤柱护巷方案设计正确,极大改善了巷道围岩的应力环境,整体设计满足生产要求,现场应用良好。130203工作面小煤柱沿空掘巷技术成功应用,为矿井开采提供了可靠的科学依据。

综放面“双硬”煤层临空煤柱宽度及承载强度校核

具有“双硬”特征煤层的工作面其护巷煤柱的极限尺寸确定与常规工作面有所不同。以榆树岭煤矿505工作面沿空掘进巷道为背景,首先测试了煤岩样的力学性质和不同高径比煤样的抗压强度,得到了不同高径比煤样峰值强度曲线;其次分析了沿空掘巷覆岩结构模型,建立了沿空掘巷护巷煤柱顶板力学模型,得到了不同宽度煤柱所受的载荷应力;建立了不同高宽比煤柱的数值模型,得到了不同高宽比煤柱的极限强度校核公式;最后通过对比不同宽度煤柱所受的载荷应力和极限强度,得出4m宽度的煤柱即可满足支护要求,并在此基础上提出了沿空掘进巷道支护工艺。现场监测结果表明,煤柱宽度为4m时,巷道整体变形量较小,巷道稳定性得到有效维护。研究结果可为小煤柱护巷宽度的确定提供参考。

近距离下煤层上覆岩层裂隙发育规律与上行开采研究

针对上行开采覆岩运动可能会使上覆煤层的整体性遭到破坏,造成上覆煤层无法开采的技术难题,以某矿9煤工作面开采对上覆5煤的影响为工程背景,采用理论分析、数值模拟、相似材料模拟等手段,研究了近距离煤层下煤开采后上覆岩层覆岩破坏情况、岩层裂隙发育规律及工作面矿压显现规律等问题,得到如下结论:近距离煤层下伏9煤开采后上覆岩层塑性区范围,其中三带判别法得垮落带高度平均9 m,导水裂隙带高度36 m;比值分析法K为19.99,大于中硬岩层7.5;围岩平衡法得上覆5煤安全开采的必要层间距为45 m,远小于5煤与9煤层间距60 m;数值模拟表明,近距离煤层下伏9煤工作面开采后上覆5煤位于下煤层开采后形成的塑性区域内,在留设保护煤柱区域内不会存在应力集中现象;相似模拟表明,近距离下伏9煤开采后,5煤最大下沉值为10 mm,模型垮落带高度基本在15 cm左右,符合矿山压力及覆岩运动发展规律;该矿近距离下伏9煤开采后上覆5煤开采是可行的。

浅埋近距离煤层工作面过平行煤柱开采强矿压显现规律

浅埋近距离煤层工作面过平行煤柱开采容易发生强矿压压架事故,严重影响工作面安全高效开采。以榆家梁煤矿43207工作面和石圪台煤矿2^(-2上)102及2^(-2上)103工作面为背景,采用理论分析、物理模拟和现场实测相结合的方法,根据间隔岩层厚度和煤柱应力传递影响角,提出了过煤柱阶段划分判据,重点分析了不同间采比G、水力压裂程度条件下,过平行煤柱不同阶段的矿压显现特征。结果表明:由于上覆遗留煤柱及倒梯形覆岩结构的作用,导致煤柱影响阶段来压时支架平均载荷最大,进煤柱阶段次之,出煤柱阶段最小,强矿压位置主要集中在出煤柱影响阶段范围;间采比越小,工作面过煤柱采动期间来压时支架平均载荷越大,间采比G=5.5较G=10在进煤柱阶段、煤柱影响阶段和出煤柱阶段分别增大14.6%、14.2%和23.5%,动载效应越明显;间采比对周期来压步距影响不大,总体上煤柱影响阶段的周期来压步距是进出煤柱阶段的1.6~2倍,周期来压步距越大造成顶板悬伸长度增大,导致工作面来压时支架载荷明显。根据过煤柱阶段不同水力压裂范围的矿压规律分析,压裂后的支架平均载荷较未压裂减小11.2%~15%,来压步距减小7.8%~20.3%,水力压裂效果较明显,可有效地降低工作面过煤柱采动的强矿压风险,为类似开采条件的强矿压控制提供借鉴意义。

近距离特厚煤层回采巷道合理布置优化研究

针对近距离煤层开采后遗留煤柱下位特厚煤层回采巷道布置的技术难题,以开滦集团唐山矿为研究对象,综合采用理论分析、数值模拟和现场实测等研究手段,对上位煤层采动后的底板破坏深度、残留煤柱底板应力分布及下位煤层巷道顶板非均布载荷下易被破坏的原因进行了研究。研究表明:上位煤层开采引起的支承应力导致的最大破坏深度为31.5 m,对下位煤层回采巷道布置产生影响;煤柱底板的垂直应力分布具有明显的非均布性,下位煤层回采巷道更易达到抗拉极限而产生变形破坏。同时对比了下位煤层四种巷道布置方式下的主应力分布特征,优选出内错式和平移式布置方式。进一步,通过巷道的应力改变量Δσ和位移改变量ΔD评估回采巷道顶板受应力及变形的不均衡程度,结合数值模拟计算和现场工业性试验数据印证,得出9~#煤层工作面回采巷道最佳内错距离为37.5 m,为特厚煤层回采巷道布置提供了借鉴依据。