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.

Safe mining technology of undersea metal mine

Xinli district of Sanshandao Gold Mine is the first subsea metal mine in China.To achieve 6 kt/d production capacity under the premise of safe mining,high-intensity mining might destroy the in-situ stress filed and the stability of rockmass.According to sampling and testing of ore-rock and backfill and in-situ stress field measurement,safety factor method calculation model based on stress-strain strength reduction at arbitrary points and Mohr-Coulomb yield criterion was established and limit displacement subsidence values under the safety factor of different limit stoping steps were calculated.The results from three years in-situ mining and strata movement monitoring using multi-point displacements meter showed that the lower settlement frame stope hierarchical level filling mining method,mining sequence are reasonable and rockmass stability evaluation using safety factor method,in-situ real-time monitoring can provide the technical foundation for the safety of seabed mining.

有限回采空间内贫矿资源无底柱分段崩落法低贫损开采方案研究

做好无底柱分段崩落法的贫损控制对于矿山经济效益及环境保护具有重要意义,但当矿床开采条件复杂、矿石品位较低时,矿石贫损控制难度将会大幅增加,在此条件下如何做好矿石贫损控制一直是崩落法开采方向的重要关注点。金川龙首矿西二采区无底柱分段崩落法采场仅可布置4个分段,回采空间十分有限,不利于矿石的贫损控制,加之西二采区矿石品位较低但经济价值较高,因此在开采过程中需要严格控制矿石贫损。针对西二采区的复杂开采条件及贫损控制需求,提出了一种“首采分段总量控制出矿、中间分段低贫化出矿、最末分段低贫化出矿+辅助进路回收残留矿石”的组合式低贫损回采方案。以西二采区为工程背景,设计并制作了一种高仿真度的物理放矿模型并对该方案展开了试验研究。结果表明:即便是在暂时不考虑回收最末分段残留矿石的情况下,该方案可使西二采区崩落法采场的矿石回收率达到75.6%,而废石混入率仅为6.0%,在确保矿石回收率的基础上显著降低了矿石贫化。该方案在现场应用后,实际的矿石回收指标与试验结果基本接近,表明该方案在西二采区有限回采空间内实现了贫矿资源低成本、高质量回收的总体目标。

浅埋房柱式采空区煤柱稳定性及控制研究

老采空区受矿区早期采煤方法的限制,具有较强的隐匿性,很难得到有效治理,为其地表构筑物建设带来巨大挑战。以昌盛煤矿房柱式老采空区治理为工程背景,采用理论分析、钻孔勘探、数值模拟以及现场瞬变电磁勘查等方法,分析了房柱式采空区覆岩裂隙特征;判别了房柱式采空区上地表的稳定性,数值模拟进一步分析得出,在新的单位载荷作用下,采场中央遗留煤柱将发生活化失稳,引起采场所有煤柱发生多米诺骨牌式破坏,进而导致房柱式采空区地表发生失稳。基于对房柱式采空区稳定特征及浆液在房柱式采空区流动的特性提出了散点式注浆充填方案,给出了浆液配比及注浆工艺。现场瞬变电磁勘查结果表明,散点式注浆充填法能有效实现老采空区的充分均匀充填,注浆效果整体良好,同时该方法可为对类似老采空区地表治理提供参考。

充填采矿法在洛宁吉家洼金矿中的应用

吉家洼金矿位于华北板块南缘、熊耳山金多金属矿集区。由于顶底板围岩条件较差,以往采用浅孔留矿法,采矿损失率、贫化率较高,也存在诸多安全、环境问题。为此矿山开展充填法采矿实践,通过“凿岩爆破→通风→顶板处理与支护→运搬→砌筑挡墙→加高溜矿井及顺路天井→充填”回采工艺循环,并采取一系列技术、安全措施,取得了较好的实践效果:采矿回采率由75%~80%提高至94%~97%,贫化率由29%~34%降低至10%~15%;吨矿产值由551~587元提高至690~712元;选矿尾砂作为充填材料,也降低了尾矿库的安全、环境风险。研究成果对类似矿山开展充填法采矿实践和研究具有一定借鉴意义。

基于FLAC3D与无人机航测的全部垮落法采煤塌陷分析

内蒙古串草圪旦煤矿位于黄河中游上段,其全部垮落法采煤导致大面积塌陷,地表生态和环境问题频发。为研究采空区地表裂缝发育规律及塌陷应力与位移场演化特征以串草圪旦煤矿6102工作面为研究对象,利用无人机航测查清了地表裂缝分布范围及规律,构建了FLAC3D数值模型并计算分析了采空区围岩应力及位移变化,将分析结果与无人机航测结果进行了相互验证。结果表明:(1)塌陷主要以地裂缝为表现形式,主要分布于矿区西北部及中西部。工作面发育2类地裂缝,一类为弧形阶梯式裂缝群,呈平行分布且以间隔5~20 m出现,大部分形成阶梯式高度为15~130 cm的错台,裂缝以3°~5°的偏角垂直工作面推进方向发育;另一类为直线型边缘裂缝带,拉张破坏严重,平行工作面外围呈带状发育,少数可展布于工作面内部,最外围裂缝至工作面的距离分别为38,53 m。(2)由于地下煤层开挖,采空区顶板出现明显的“马鞍状”拉应力集中区,且随着开挖的推进地表集中区拉应力先增大后减小,最大值为0.181 MPa;(3)采空区顶部完全垮塌,地表垂直位移最大值在采空区正中间,最大值约5.5 m;地表水平位移最大值位于采空区煤柱正上方,最大值1.93 m。(4)数值模拟计算的沉降量、裂缝角与无人机航测数据基本一致。研究成果可为煤层开采带来的生态环境问题解决方案提供参考依据。

煤矿充填开采下顶板沉降研究

充填采矿可以有效控制岩层移动、抑制地表沉陷、减轻地质灾害,并且能够处理或利用一定的固体废弃物,有效改善矿山上覆岩层的力学环境,减轻顶板压力。以平凉某煤矿为工程背景,研究煤矿充填开采条件下坚硬顶板沉降变形情况,构建了顶板力学模型,对于初期来压采用四边固支的边界条件,利用变分法中伽辽金变形方程求选用不同挠度表达式的解;另对周期来压选用三边固支一边自由的边界条件,采用变分法中里兹变形方程进行求解,得出充填后顶板挠度显著减小,初期来压时减小38.74%,周期来压时减小66.84%。并得到充填开采顶板沉降变形规律,随着充填体弹性模量k值增大,顶板下沉位移显著减小。

云锡高峰山矿段矿柱回采方案研究

为了更合理地回收云锡老厂分公司残矿资源,运用FLAC3D数值模拟软件对高峰山矿段残留矿柱回采进行模拟分析,提出6种不同的矿柱回收方案,针对分析结果确定了合适的矿柱回采工艺,并开展了工业试验。结合矿山实际情况,从多个维度分析剩余矿柱是否具备回收条件和回收价值。结果表明:可采用进路规格为4 m×4 m的两步骤胶结充填采矿法进行矿柱回采,一步骤胶结充填强度大于3.52 MPa,二步骤充填强度大于1.08 MPa;矿段内有4条矿柱相对完整、保有资源量大且品位高,现阶段具备回采条件,其中南盘区4#盘区矿柱需在锡精矿市场金属价格大于24.48万元/t时进行回采,其余3条矿柱可在锡精矿市场金属价格大于10.05万元/t时进行回采。

急倾斜中厚煤层单一巷道放顶煤采煤方法研究与应用

为解决某矿急倾斜中厚煤层倾角及厚度变化大的开采问题,提出了“急倾斜中厚煤层单一巷道放顶煤采煤方法”。该采煤方法是沿急倾斜煤层倾斜方向划分为若干区段,每个区段沿急倾斜煤层走向仅布置1条巷道。此巷道服务于1个采煤区段,担负工作面通风、运输和行人等任务。对单一巷道放顶煤采煤方法的巷道布置、综放工艺和沿空留巷方法进行了探讨。实践表明,该采煤方法使采煤工作面形成全负压通风,避免了巷道与采空区窜风,杜绝了采空区瓦斯积聚和遗煤自燃,实现了采煤机械化,提高了急倾斜中厚煤层的开采效率和煤炭回收率。单一巷道放顶煤采煤法为类似急倾斜煤层安全、高效开采提供了技术支撑。

自然崩落法矿山矿岩赋存特征精细调查与辅助致裂崩落效果研究

自然崩落法采矿技术对矿岩赋存特征要求严苛,矿岩崩落特性直接影响自然崩落法矿山矿岩崩落速率及出矿块度。通过人工辅助致裂增加矿岩体内部裂隙发育程度实现矿岩预处理,是当前国外自然崩落法矿山生产过程的重要技术手段。本文以我国首座自然崩落法矿山铜矿峪矿向深部转移首采区开采工程为背景,开展了矿岩赋存特征精细调查与水压致裂矿岩预处理试验研究。结果表明:铜矿峪矿410 m中段5号矿体首采区矿岩坚硬、中等完整~较完整,岩体质量等级为Ⅱ~Ⅲ类,矿岩中等可崩~难崩,矿岩崩落破碎特性为中等破碎~大块较多;岩体赋存特征精细调查对于深入了解矿岩崩落特性意义重大;通过钻孔摄像技术获取了水压致裂矿岩预处理试验前后钻孔孔壁图像并揭示了水压致裂过程产生的新裂隙,有效改善了矿岩结构面发育程度;通过对崩落顶板监测及出矿口块度统计分析显示首采区生产期崩落速率提高了3倍多、出矿口大块率降低了58.3%,为铜矿峪矿转深部开采过渡期产能平稳衔接提供了坚实保障;初步形成了水压致裂矿岩预处理技术及装备体系,可支撑我国现代自然崩落法采矿技术进一步推广应用。

下向进路充填采矿法深部矿岩破坏机理数值模拟研究

针对嵩县山金深部矿体采用下向进路充填采矿法开采矿岩破坏机理及地压显现技术问题,采用Rhino+Griddle+Flac 3D快速建模技术,对矿区下向进路开采1~8 a矿岩应力及位移变化规律进行研究。模拟结果表明:最小主应力随深度的增加而增加,靠近底部较大;未开采采场起到了临时矿柱的作用,应力集中现象较明显,同时在采场附近的充填体中也形成应力卸压区;各中段的位移随开采时间的增加而不断增大,采场顶板的最大位移主要出现在顶板中间,在矿山不断向深部推进的过程中,最大位移值呈上升趋势。

相邻分层进路交错垂直开采下进路围岩稳定性数值模拟

针对下向分层充填采矿相邻分层进路交错垂直开采条件下的进路围岩稳定性问题,建立进路围岩结构受力模型,并分析不同开采条件下充填假顶对进路围岩稳定性影响特征,得到三期进路开采下充填假顶力学状态。利用FLAC3D数值模拟对下分层“三期”进路开采下的进路围岩应力演化特征进行模拟分析。结果表明:在下分层一、二期进路回采充填过程中,两矿体侧帮在推进方向上,水平应力呈驼峰状分布,一期开采过程中,进路两帮垂直位移出现对称的正负值;三期进路回采过程中,未回采进路矿体承载上覆载荷越来越大,危险系数逐渐增加;受采动影响,下分层边缘进路稳定性较差,尤其无假顶边缘进路回采时,岩体稳定性差,危险系数高,回采时需要加强支护。

郭庄煤矿条带工作面充填开采工艺设计

为缓解采掘衔接紧张、延长矿井服务年限,郭庄煤矿计划利用膏体充填采煤法对“三下”压煤进行开采。在郭庄煤矿CT1101工作面现有地质条件和采区巷道布置的前提下,设计了条带工作面充填开采工艺流程,包括开采顺序设计、开采阶段设计和充填阶段设计,为充填工艺实施提供了技术支持。

灌注充填法在煤矿采空区场地治理中的应用

研究区原为煤矿采空区,场地内拟建高层住宅楼,为满足建筑物承载力要求,采用灌注充填法对采空区进行治理。本文分析了灌注充填法在煤矿采空区场地治理的可行性、治理方案及治理流程,建议:一般注浆孔采用正三角形布设,帷幕注浆孔采用正三角形双排布设;采用“一次注浆”和“上行式分段注浆”工艺进行注浆;主要注浆材料为粉煤灰、水泥、添加剂等;在注浆治理施工前,对配置后形成的浆液性质进行测试,并确定最佳配比。研究区采用灌注充填法注浆,注浆质量良好,效率高,工程造价低,采空区及垮落带、巷道及裂隙带得到有效充填,注浆结石体岩心完整,证明了该方法治理煤矿采空区的可行性。

某磷矿房柱法开采空区治理技术研究与应用

某磷矿采用脉内开拓盘区房柱法开采,在开采过程中形成了一定规模的采空区,给未来生产造成了较大的安全隐患。为了消除或减小采空区对矿山安全开采的危害,针对采空区存在的现状,进行工程地质调查,采空区治理及安全监测措施等研究,提出了采用废石干式充填方法进行空区治理方案,并对充填准备和充填步骤进行详细部署;同时,对空区封堵工艺及封堵墙规格进行设计,根据采空区分布特点布置位移监控报警仪和地压监测报警仪,实现采空区地压活动实时监测和预警预报。研究结果为矿山的采空区治理和安全有序生产提供决策依据和技术保障,也为类似条件矿山提供一定的借鉴。

百贯沟煤矿特厚煤层开采方案与地表注浆充填减沉效果及经济效益研究

百贯沟煤矿2509工作面上方有公路、煤棚等地面设施,工作面回采过程中地表移动变形会影响地面设施的稳定性。采用了概率积分法中的有限采动方法对2509工作面开采过程的地表沉降进行了理论计算,采用了数值模拟预测了不同采高下的地表沉降。经对比不同方案的减沉效果和经济效益,推荐采用“前256 m充填开采”方案进行开采,综合考虑浆液的扩散半径与填充体的强度,浆液配比选用固化剂∶粉煤灰∶水为1∶5∶15,根据监测结果,减沉效果显著,桥梁减沉率为75.75%,储煤棚减沉率为86.33%,煤仓减沉率为87.17%。

基于3Dmine的采空区治理工程实践

通过对某金矿采空区资料收集及现场调查,利用3Dmine软件建立了该金矿采空区+巷道三维数字模型,准确获得了各中段采空区的实际边界和采空区形态等相关信息。针对采空区情况,结合矿区生产实际,经综合分析研究,提出了采空区治理方案,即:对矿区已经贯通连成一体的采空区群/塌陷坑(四中段以上)采用地表废石充填,四中段未贯通的采空区采用中深孔强制崩落顶板,将上部自地表“灌入”的废石充填到采空区,同时采取密闭隔离的方式联合治理;对于其余地段的采空区,已经结束回采且无法进入的区域采取在中段石门密闭隔离的方式进行治理,尚在开采的其他采空区采取施工措施工程进行坑内毛石回填并密闭隔离方式治理。通过多项措施的综合运用,彻底消除了发生大面积地压活动并引起地面塌陷的隐患,为井下正常生产作业创造了良好的条件。

低品质固废协同制备绿色充填胶凝材料

随着国家对环境保护要求日趋严苛,水泥价格逐年提高,以水泥作为充填胶凝材料的充填采矿成本不断提高,利用低品质固废开发低成本绿色充填胶凝材料替代水泥,对于提高矿山经济效益具有重要的现实意义。以邯邢地区某磁铁矿选矿全尾砂为骨料,利用周边固废资源进行矿渣基胶凝材料配比优化试验研究,获得矿渣基胶凝材料的配比:盐激发剂13%+碱激发剂11%+矿渣粉76%。胶砂比1∶4、料浆浓度66%的全尾砂矿渣基胶凝材料胶结充填体7d、28d强度分别为3.42 MPa和4.50 MPa,分别为42.5水泥强度的3.1倍和2.5倍,成本约为42.5水泥成本的70%。在此基础上,进一步利用钢渣固废,开展钢渣基全固废绿色充填胶凝材料的配比试验研究,获得钢渣基胶凝材料的配比:33%钢渣微粉+14%硫酸盐激发剂+53%矿渣微粉。胶砂比1∶4、料浆浓度66%的全尾砂钢渣基胶凝材料胶结充填体7d、28d强度分别为3.28 MPa和4.50 MPa,分别为42.5水泥强度的3.2倍和2.5倍,成本约为42.5水泥的60%。研究结果可为低成本绿色胶凝材料研发提供新思路。

大采高工作面甩刀把技术方案设计与选择研究

为了解决大采高工作面甩刀把技术难题,结合大采高工作面煤壁易片帮、设备大型化、矿压显现剧烈、撤架通道断面大等特点,提出了提前停采法、直接贯通法、充填贯通法三种甩刀把技术方案。根据长平矿4321大采高工作面甩刀把工程实际,运用价值工程理论对三种技术方案的价值系数进行了分析计算,分析结果表明:充填贯通法价值系数要高于其他两种技术,为该工作面甩刀把施工作业的最优技术方案。现场实践证明:充填贯通法具有施工工艺简单、工期短、资源回收率高、安全保障程度高等优点,能够实现大采高工作面安全、高效、快速甩刀把的目的。

覆盖性岩溶区大直径密集灌注桩施工技术研究

岩溶区灌注桩施工常出现塌孔、漏浆、涌水等,尤其是直径较大的灌注桩。为解决岩溶区地铁车辆段大直径灌注桩施工技术难题,以深圳岩溶区某地铁车辆段桩基施工为例,研究岩溶区地铁车辆段大直径灌注桩施工技术,探讨不同尺寸溶洞处理的施工方法,分析岩溶区大直径桩基施工效果。结果表明,溶洞为无填充或半填充状态时,溶洞高度不大于1.0m时,采用注浆法处理,溶洞高度为1.0~5.0m时,采用充填法处理;溶洞为全填充状态时,溶洞高度不小于1.0m时,采用注浆法处理;溶洞高度不小于5.0m时,采用全套管成孔工艺施工灌注桩;桩身混凝土芯样抗压强度值为40.8~59.1MPa;岩溶区桩基施工完成后,Ⅰ类桩占比为97.28%,Ⅱ类桩占比为2.72%。