High prestress truss cable support principle and its application in large cross section coal roadway

With the enlarge of cross section of roadway, the radius of plastic area and broken area increase, and the tensile stress and shear stress distributing in roof coal-rock layers relevantly increase, which induce support effect not obvious for ordinary bolt（cable）. While bounding point and support structure of the truss cable is in vertex angle of roadway, and supplies coal-rock layers in bounding area with the horizontal and vertical pressure, so it settles the support problems in large cross section coal roadway. From the point of view of mechanics, gave emphasis on the invalid mechanics of ordinary bolt （cable） in large cross section coal roadway and supported mechanics of prestress truss cable. The author successfully used this technique in Wuyang Mine, and had the huge economic efficiency and the social benefit.

Key technologies and equipment for a fully mechanized top-coal caving operation with a large mining height at ultra-thick coal seams

Thick and ultra-thick coal seams are main coal seams for high production rate and high efficiency in Chinese coal mines, which accounts for 44 % of the total minable coal reserve. A fully mechanized top-coal caving mining method is a main underground coal extraction method for ultra-thick coal seams. The coal extraction technologies for coal seams less than 14 m thick were extensively used in China. However, for coal seams with thickness greater than 14 m, there have been no reported cases in the world for underground mechanical extraction with safe performance, high efficiency and high coal recovery ratio. To deal with this case, China Coal Technology ＆ Engineering Group, Datong Coal Mine Group, and other 15 organizations in China launched a fundamental and big project to develop coal mining technologies and equipment for coal seams with thicknesses greater than 14 m. After the completion of the project, a coal extraction method was developed for top-coal caving with a large mining height, as well as a ground control theory for ultra-thick coal seams. In addition, the mining technology for top-coal caving with a large mining height, the ground support technology for roadway in coal seams with a large cross-section, and the prevention and control technology for gas and fire hazards were developed and applied. Furthermore, a hydraulic support with a mining height of 5.2 m, a shearer with high reliability, and auxiliary equipment were developed and manufactured. Practical implication on the technologies and equipment developed was successfully completed at the No. 8105 coal face in the Tashan coal mine, Datong, China. The major achievements of the project are summarized as follows： 1. A top-coal caving method for ultra-thick coal seams is proposed with a cutting height of 5 m and a top-coal caving height of 15 m. A structural mechanical model of overlying strata called cantilever beam-articulated rock beam is established. Based on the model, the load resistance of the hydraulic support with a large mining height for top-coal caving method is determined. With the analysis, the movement characteristics of the top coal and above strata are evaluated during top-coal caving operation at the coal face with a large mining height. Furthermore, there is successful development of comprehensive technologies for preventing and controlling spalling of the coal wall, and the top-coal caving technology with high efficiency and high recovery at the top-coal caving face with a large mining height. This means that the technologies developed have overcome the difficulties in strata control, top-coal caving with high efficiency and high coal recovery, and enabled to achieve a production rate of more than 10 Mtpa at a single top-coal caving face with a large mining height in ultra-thick coal seams; 2. A hydraulic support with 5.2 m supporting height and anti-rockburst capacity, a shearer with high reliability, a scraper conveyor with a large power at the back of face, and a large load and long distance headgate belt conveyor have been successfully developed for a top-coal caving face with large mining height. The study has developed the key technologies for improving the reliability of equipment at the coal face and has overcome the challenges in equipping the top-coal caving face with a large mining height in ultra-thick coal seams; 3. The deformation characteristics of a large cross-section roadway in ultra-thick coal seams are discovered. Based on the findings above, a series of bolt materials with a high yielding strength of 500-830 MPa and a high extension ratio, and cable bolt material with a 1 × 19 structure, large tonnage and high extension ratio are developed. In addition, in order to achieve a safe roadway and a fast face advance, installation equipment for high pre-tension bolt is developed to solve the problems with the support of roadway in coal seams for top-coal caving operation with a large mining height; 4. The characteristics of gas distribution and uneven emission at top-coal caving face with large mining height in ultra-thick coal seams are evaluated. With the application of the technologies of gas drainage in the roof, the difficulties in gas control for high intensive top-coal caving mining operations, known as ＂low gas content, high gas emission＂, are solved. In addition, large flow-rate underground mobile equipment for making nitrogen are developed to solve the problems with fire prevention and safe mining at a top-coal caving face with large mining height and production rate of more than 10 Mtpa. A case study to apply the developed technologies has been conducted at the No. 8105 face, the Tashan coal mine in Datong, China. The case study demonstrates that the three units of equipment, i.e., the support, shearer and scraper conveyor, are rationally equipped. Average equipment usage at the coal face is 92.1%. The coal recovery ratio at the coal face is up to 88.9 %. In 2011, the coal production at the No. 8105 face reached 10.849 Mtpa, exceeding the target of 10 Mtpa for a topcoal caving operation with large mining height performed by Chinese-made mining equipment. The technologies and equipment developed provide a way for extracting ultra-thick coal seams. Currently, the technologies and equipment are used in 13 mining areas in China including Datong, Pingshuo, Shendong and Xinjiang. With the exploitation of coal resources in Western China, there is great potential for the application of the technologies and equipment developed.

面间煤柱与顺槽“掘-充-留”一体化科学问题与技术

我国将煤炭作为兜底保障能源的局面短期内无法改变,仍将长时间面临煤炭资源保护与煤基固废利用率低的难题。通过创新采掘方法,同时实现提高煤炭资源回采率、规模化处置煤基固废,为煤炭行业绿色可持续发展提供了新途径。在深入调研煤炭资源开采技术发展现状的基础上,提出了煤矿“掘-充-留”掘进新工法。从大断面巷道快速掘进、连续高效充填和巷道安全留设3个方面,通过理论分析、数值模拟等手段,系统论述了“掘-充-留”工法的科学问题和关键技术,研究结果表明:①针对大断面巷道快速掘进、掘进工作面围岩稳定性控制等工程难题,凝练了煤岩特性与掘进机截割参数匹配机制、覆岩载荷空间传递机制与围岩变形机理、锚杆/索-顶板相互作用关系及支护机制3个科学难题,构建了以掘进区地质环境超前实时感知、落-装-运煤多工序智能协同作业、钻锚支架随掘随支围岩时效控制和大断面巷道防漏风及通风优化为核心的技术体系;②从大断面巷道承载体系及时构建及其承载性能调控两个方面凝练了连续高效充填的科学问题,包括充填体-煤层-锚杆/索协同承载机制、多元固废基充填材料水化固结机制,明晰充填体物理力学特性时空演化规律,建立了充填空间安全高效搭建、充填材料工作性能调控、充填材料流动-固结感知为核心的连续高效充填关键技术体系,相关理论与技术的突破可以为充填材料的原材料优选及配比设计、添加剂开发/选型及工作性能调控、掘进速率及充填步距优化设计、充填体固结监测等提供基础理论依据;③基于巷道安全留设及全生命周期内围岩易断裂、易片帮和易损伤等关键难题,阐述了巷道围岩应力场时空分布特征、巷道变形与损伤演化机制、巷道围岩工程质量监测与稳定性调控理论3个科学问题,形成了以巷道围岩稳定性智能预警、巷道围岩变形控制为核心的关键技术体系。开展煤矿“掘-充-留”工法的科学研究与工程示范,实现固废规模化处置-面间煤柱高效回收-顺槽快速掘进的协同,可以推动煤炭行业绿色低碳转型发展。

矿井涌水量预测方法及对比分析-以新疆东沟煤矿为例

矿井涌水量的预测对煤矿的安全生产具有重要意义。水文地质参数的准确选择、计算方法的选择对矿井涌水量的准确预测影响巨大,同时考虑到矿井开采实际,涌水量不是从开采初期就稳定不变的,而是动态变化的。为提升涌水量预测的准确度,更好地为煤矿开采服务,在分析新疆东沟煤矿地质及水文地质条件,选取准确水文地质参数的基础上,选择了2种适用于东沟煤矿的涌水量预测方法进行了对比分析。计算结果表明:①非稳定流释水-断面流法计算得到的涌水量呈现动态变化特征,采掘强度稳定后,变化幅度变小,最后趋于稳定;②采用大井法、非稳定流释水-断面流法计算得到的预测涌水量分别为3396、599.87~612.9 m^(3)/d与实际涌水量480 m^(3)/d分别相差607.5%>24.97%~27.69%;③根据矿井实际开采产生的涌水量数据验证分析,采用非稳定流释水-断面流法计算得到的涌水量与实际开采产生的涌水量基本吻合,涌水量预测结果的准确度依次为非稳定流释水-断面流法>大井法;④在资料充足、参数准确的情况下,建议优先选择非稳定流释水-断面流法计算涌水量,在补水边界条件差且符合大井法要求的条件下建议首先选用大井法。本次计算结果一方面充分验证了非稳定流释水-断面流法的准确度,另一方面为煤矿矿井涌水量计算提供了借鉴,同时也为东沟煤矿的安全生产提供了数据支撑。

新景矿大断面岩巷综掘技术研究与应用

为提高掘进速度,保证巷道稳定,在新景矿15号煤采区集中辅助运输巷开展了大断面岩巷综合机械化掘进技术的研究。在分析当前施工工艺以及支护中存在问题的基础上,提出了以EBZ320D掘进机和CMM2-25型锚杆钻机为主要设备的综合机械化岩巷掘进作业线。理论分析了锚杆索围岩强度强化理论,结合现场实际情况,设计了以不同长度锚索为主的支护方式。现场应用表明,应用新的综合机械化掘进技术后,巷道变形量小,掘进速度快,施工成本低,经济社会效益显著,应用效果良好。

EBZ-318综掘机在大断面岩巷掘进施工中的应用

为提高矿井岩巷综掘速率,解决矿井使用钻爆法施工进尺低、劳动强度高等问题,榆树岭煤矿引进EBZ-318H型综掘机进行北风斜井施工。现场应用表明:与传统炮掘相比,在生产进尺方面,采用综掘机后,掘进速度提升约2倍,最高日进尺达到8 m,月进尺达到156 m;在经济效益方面,每月减少用工270人,整条巷道节省费用约88.2474万元。

区段煤柱下大断面回采巷道不同成巷方式分析研究

为了探究在区段煤柱下大断面巷道在掘进时受到扰动最小的一种成巷方式,以乌兰色太煤矿掘进52202工作面运输顺槽为研究背景,针对该工作面实际地质资料,通过数值模拟分析了大断面巷道在不同成巷方式条件下的塑性区形态、应力场及位移场分布规律。结果表明,先掘进5.4 m宽正常巷道,后扩帮2 m的成巷方式为最优成巷方式,将其应用于工程实践,为同类型区段煤柱下大断面巷道提供参考依据。

矿井采煤过程中大断面巷道支护技术研究

煤炭资源是中国重要的能源资源之一,然而在矿井采煤过程中,巨大煤矿的开采和应力变化等因素导致支护不足和大断面巷道变形严重。为了解决这一问题,需要开展更深入、更系统的研究。首先介绍了大断面巷道的特点以及在采煤过程中存在的支护难题,包括巷道变形、支架开裂等问题。然后分析了传统支护方式存在的不足之处,并提出了一种新型支护技术——填充式支护技术。该技术采用填充材料将巷道周围空隙填满,从而增强了支护效果,提高了大断面巷道开采的安全性和可靠性。

厚煤层大断面沿空巷道变形破坏机理及控制技术

针对沿空巷道受多次采动叠加影响极易发生变形失稳破坏的难题,以某矿1505W工作面厚煤层综放开采工作面为研究背景,综合采用理论分析、现场实测、数值模拟等多种研究方法探讨分析了沿空巷道围岩失稳破坏机制,并提出了围岩“浅部、深部、表层”控制方案。现场试验结果表明,提出的控制方案能够使巷道浅、深部围岩形成统一的整体,有效抑制了沿空巷道围岩变形,提高了巷道的稳定性。

高应力大断面巷道围岩注浆加固机理及其应用

为解决高应力大断面巷道服务期间变形严重的问题,利用莫尔-库仑准则和力学平衡原理,开展巷道松动圈注浆加固机理和力学模型分析,采用FLAC3D仿真计算软件对4种不同支护形式进行数值模拟,研究不同支护状态下巷道变形演化规律,并开展现场工程实践。研究结果表明:增加承载层的长度可以有效提高巷道围岩的稳定性,注浆加固可黏合破碎岩体,形成骨架结构;分层掘进可减小巷道围岩自由面,从而减缓应力释放速度;滞后注浆可在应力基本释放后对破碎岩体进行最大程度的黏合加固,加固后的松动圈形成整体结构后配合锚杆索支护,能够有效减少围岩破坏以及塑性区发育。实践证明:采用“分层掘进+滞后注浆+锚索补强”支护方案后,掘进期间,顶底板最大移近量约为50 mm,两帮最大移近量约为140 mm,底鼓量约为75 mm;5303工作面回采期间,顶底板最大移近量约为125 mm,两帮最大移近量约为350 mm,底鼓量约为173 mm,虽然回采期间巷道变形量较大,但整体变形可控,能满足深部大断面巷道支护要求。“分层掘进+滞后注浆+锚索补强”支护方案能够有效解决高应力大断面巷道严重变形问题,可在类似地质条件的矿井推广。

高家庄煤矿大断面硬岩巷道智能化掘进系统研究与应用

针对高家庄煤矿东翼轨道大巷大断面硬岩掘进工作面智能化水平较低、生产效益差、存在安全隐患等问题,提出了高家庄煤矿大断面硬岩掘进工作面智能化高效生产模式,形成了大断面硬岩掘进工作面系统,建立了以快速掘进智能综合控制一体化平台为中心,自移机尾、带式输送机和除尘系统为基础,以掘锚一体机为主体,将人工智能、自动化装备与大断面硬岩快速掘进生产活动相融合,实现了大断面硬岩掘进工作面智能化掘进。智能化工作面掘进实现单班工作人员较传统工艺减少了50%,破岩速度提高了2倍,日掘进尺由1.6m提高到4.8m,故障率下降8%,智能化掘进最大限度提高了巷道掘进效率及人工效率。

大断面巷道围岩变形机理及控制技术应用研究

为解决采空区下大断面巷道围岩稳定性差的问题,同德矿以5316工作面为工程背景,通过理论分析和数值模拟相结合的方法,对地质复杂条件下大断面巷道承载结构的应力环境变化、巷道变形破坏表现、顶板锚索破断深层次原因、巷道围岩控制技术展开研究。运用FLAC 3D对工作面开采后的破坏规律进行模拟,对支护参数进行优化,最终确定支护方案。通过现场变形监测,巷道围岩变形量得到了有效控制,在支护效果和成本控制方面新支护方案都较为理想。

王庄煤矿构造应力扰动下大断面巷道围岩控制技术研究

针对王庄煤矿9105工作面受构造应力影响导致的大断面巷道变形严重问题,采用数值模拟与现场监测相结合的方法,研究了大断面巷道变形特征及其围岩控制技术。分析表明,巷道断面尺寸效应在4.5 m×4.5 m以上时表现更加突出,不利于巷道稳定;随着侧压系数的增加,巷道顶底板及两帮移近量均呈现增加趋势,侧压系数越大,巷道变形增加越剧烈;9105工作面巷道由于宽度较大,导致巷道顶板及两帮变形严重。据此设计了大断面巷道采用“高强度螺纹钢锚杆+预应力锚索+金属网+工字钢棚”联合支护技术。通过工程实践,顶底板移近量降低48.1%,两帮移近量降低55.4%,实现了构造巷道的有效控制。

大断面大压差远程控制平衡风门技术研究

随着煤矿开采逐渐向深部延伸,平衡风门作为重要的通风设施在井下的应用越来越广泛。然而,当大断面风门两侧存在较大压差时,会导致一系列问题,容易使风门受到破坏。为解决这一问题,对平衡风门进行了重新设计,增加了抗变形、三维可调节、就地智能控制和远程解锁短路排烟等功能。研究结果显示,在外形尺寸不变的情况下,新设计的风门自重减轻了约50%,但其强度得到增强,能够适应巷道变形量达到200mm。通过有限元分析对门扇、门框、迎风面等三个部件进行数值模拟计算,发现在16000N载荷下,门扇出现了局部失效,且最大位移发生在距离合页轴最远端的门扇受载荷面上。当巷道四周受到压力使门框产生最大变形量达到200mm后,风门仍能继续承受3000N的压力,未出现失效情况。当井下风压达到1000Pa时,最大位移出现在左门扇受载荷面的右下角位置,出现了局部失效,但并不影响风门的使用。经现场试验验证,平衡风门在一定矿压和大风压的情况下,正常使用且满足调风需求。研究结果表明,这种具备远程自动控制功能的大断面大压差的新型平衡风门能够提高风门的稳定性,确保通风系统的高效稳定运行。

大断面一次成巷爆破数值模拟及试验研究

为有效解决大断面掘进爆破作业中存在的技术难题,在大断面巷道中采用孔间多时序一次成巷爆破技术。利用LS-DYNA有限元数值模拟软件,通过改变大断面巷道炮孔掏槽方式、孔间起爆时差,进行数值模拟计算。在此基础上确定了掏槽方式、炮孔布置方式等关键爆破技术参数,并进行了现场试验及应用。结果表明:与分步开挖相比,采用孔间多时序全断面一次掘进成巷爆破技术后,巷道成型效果好、炮孔利用率提高18%。改进后的爆破方案有效地解决了大断面分步开挖中面临的问题,对地下矿大断面掘进爆破巷道成型及控制具有一定的参考价值。

煤矿井下大埋深采区轨道巷支护技术研究与应用

深入探讨了大断面巷道支护技术在煤矿中的应用,分析了掘进区域的地质构造、煤层结构及巷道位置对支护方案的影响,并通过研究具体案例,明确了巷道尺寸、形状设计、地压和冲击地压等因素对选择支护方案的重要性。在实际应用中,针对研究区域的砾岩层和冲击地压危险区域,采用了高预应力强力锚杆锚索组合支护方式,并辅以喷射混凝土的联合支护方式,而且通过地质勘探和调整巷道尺寸,使得支护结构可以更好地适应煤层和地层的复杂变化,结果表明,该支护方案可以有效提高巷道的稳定性和安全性。

充填支柱在大采高工作面过空巷支护中的应用

为解决长治仙泉煤业15105工作面存在数量众多的空巷,可能导致回采过程中出现强烈动载发生顶板事故的问题,采用FLAC3D数值模拟软件对工作面临近空巷期间超前支撑应力情况进行计算,并以此为依据设计充填支柱参数,通过改变注浆材料配比,利用相同材料获得了不同抗压强度支撑物,满足了充填支柱不同结构要求。实践证明:在采用充填支柱对工作面空巷进行支护后,工作面在回采过程中未发生大规模片帮、冒顶和支架压死情况,工作面顺利通过空巷。

大断面巷道变形破坏特征及支护设计应用

针对煤矿快速掘进下大断面巷道支护难题,以黄陵矿业一号煤矿1010回风平巷为研究对象,采用数值模拟和理论分析等研究手段,探究大断面巷道围岩变形破坏特征,给出了巷道支护方案并进行了稳定性验证。结果表明:大断面巷道未支护条件下,围岩发生大变形区域较大,肩角、底角处剪切应力集中,塑性破坏范围较大。根据极限平衡理论结合数值模拟结果,采用左旋螺纹钢锚杆+金属网+金属梁+锚索支护方式,支护后巷道锚杆、锚索有效防治了岩层变形破坏,控制了顶板下沉,限制了两帮变形,制止了底鼓发生,为矿井安全高效开采提供了保障。

大断面煤巷掘进支护参数优化及作业滞后距离研究

为解决大断面煤巷支护难度大且效率低,导致采掘比例不协调进而影响煤矿生产效率的问题,在对工作面地质和现支护方案所存在问题分析的基础上;基于FLAC3D软件对不同支护方案对应工作面围岩的稳定性进行对比,确定采用方案二对支护方案进行优化;最后,在实施层面对掘进工艺和支护作业的滞后距离进行确定,实践表明,采用多工序交叉平行作业可直接提高掘进效率25.3%.

复杂地质条件下大断面隧道揭煤防突技术研究

现代隧道工程施工易遇到复杂地质,不仅增加隧道施工难度,而且还容易使工程中出现各种问题,不利于整个隧道工程的顺利建设。遇到复杂地质条件时,施工单位应采取合理的方式对施工现场进行处理,其中,大断面隧道揭煤防突技术较为常见的一种。基于此,针对复杂地质条件特点,提出了一种大断面隧道揭煤防突技术,并以某隧道工程为研究对象,对该揭煤防突技术的具体应用进行了分析,以此为现代复杂地质条件下更好地对隧道工程建设提供支持。