托顶煤巷道锚固“梁-拱”结构分类及顶板冲击失稳机制

我国煤矿托顶煤巷道冲击地压频发,且冲击动载下顶板灾害尤为严重。为探究托顶煤巷道顶板锚固结构类型和冲击失稳机制,以陕西某矿301工作面回风巷道大面积冲击垮顶为工程背景,运用相似实验、理论分析及数据统计等方法,分析了托顶煤巷道围岩应力、位移和巷表加速度的动载响应特征,研究了顶煤厚度与支护构件影响下顶板锚固结构的分类特征,探究了弹性波下托顶煤巷道的应力响应机制,提出顶板锚固“梁-拱”结构的冲击失稳机制,评估了301工作面回风巷道的抗冲能力,并提出了相应的抗冲支护优化方案。结果表明:①冲击动载下托顶煤围岩应力和位移等监测数据验证了顶板存在内、外层的梁或拱形锚固结构,因顶煤厚度增加,顶板内层锚固结构存在由“梁”向“拱”的转换;②基于顶煤厚度与支护构件相对关系,将顶板锚固结构划分为薄顶煤的“叠加梁-拱”、厚顶煤的“组合梁-拱”和特厚顶煤的“组合拱”,建立了厚煤梁由“梁”向“拱”转化的临界厚度指标;③顶板锚固梁结构和锚固拱结构的冲击失稳机制为动静载荷下分别达到其拉伸、剪切强度极限后破坏,锚固“梁-拱”结构对冲击载荷的放大效应受其尺寸影响明显;④特厚顶煤的“组合拱”结构中内层拱承载强度较低,可增加锚杆长度提升内层拱厚,对应的“组合拱”结构的承载能力上升明显,与抗冲能力评估结果相符。

托顶煤巷道易片冒顶板变形机理与超前导管预注浆控制技术研究

目的 为探究厚煤层易片冒区域托顶煤巷道顶板变形破坏机理,并对易片冒区托顶煤巷道顶板进行有效控制,方法 以常村煤矿2701工作面皮带运输巷为例,通过等截面梁理论分析托顶煤巷道顶板破断成因,研究托顶煤巷道顶板的稳定性与巷道宽度和顶煤强度的关系。通过极限平衡准则得到巷帮位移的计算公式,证明托顶煤巷道具有帮顶协同变形机制。建立托顶煤巷道数值模型,研究巷道埋深、侧压系数、顶煤厚度和顶煤强度与托顶煤巷道围岩稳定性的关系。结果 结果表明:巷道埋深越大,其对托顶煤巷道两帮稳定性的影响越大;侧压系数的增加对巷道两帮和底鼓量的影响更大,对顶板影响较小;顶板下沉量与顶煤厚度呈正相关,底鼓量则与顶煤厚度呈负相关;顶煤强度的增加使巷道顶板下沉量与两帮移近量均近似呈线性减小趋势,底鼓量基本保持不变。结论 通过幂律型流体柱形渗透注浆扩散理论得到超前导管注浆半径,由此提出托顶煤巷道超前导管预注浆帮顶联合控制技术,成功控制易片冒托顶煤巷道顶板冒落问题,可为类似地质条件的托顶煤巷道顶板控制提供借鉴。

特厚煤层综放开采合理放煤工艺参数研究

针对不连沟煤矿特厚煤层综放开采放煤工艺参数确定的合理性问题,通过实测特厚煤层单轮顺序放煤时单个支架的连续放煤时间,在倾向方向基于“大、中、小、微”放煤理念确定了“大”放煤、“中”放煤、“小”放煤、“微”放煤的循环内位置和放煤间距;在走向方向通过布置多点位移计测试了不同顶煤高度、不同循环时的顶煤运移轨迹曲线,得出在倾斜方向的顶煤移动轨迹曲线方程,确定不同放煤步距时的工艺损失。研究结果表明:单放煤口充分放煤时,工作面倾向方向影响距离6~12架,倾向单架放煤影响半径平均7.6 m;循环内两端“大”放煤、中间“中”放煤、其余“小”放煤和“微”放煤交替;本架放煤在垂高12.3 m层位的走向影响距离平均4.9 m,在垂高8.3 m层位的走向影响距离平均3.8 m,拟合确定了不同放煤步距的顶煤走向运移方程,理论得出循环步距0.8 m比1.6 m减少煤炭损失694 t。研究结果为指导不连沟煤矿特厚煤层综放开采合理放煤和提高资源回收率提供依据。

厚夹矸顶煤放出率计算方法研究

针对含厚夹矸放顶煤开采的顶煤放出率难以计算的现状,本文以淮北朱仙庄煤矿Ⅱ863工作面为研究背景,采用散体介质流相似模拟试验以及顶煤放出率现场测定试验,研究了不同层位的顶煤回收率,并分析其运动规律,研究结果表明:相似模拟试验中顶煤平均放出率78%,现场试验顶煤平均放出率77.8%;不同层位顶煤放出率呈现“两头低中间高”的规律;该研究不仅实现了含厚夹矸顶煤放出率的计算,还为结构复杂的厚夹矸顶煤开采提供了科学依据。

矿震诱发高应力巷道厚顶煤动力失稳机制

【目的】厚煤层沿底掘进煤巷普遍存在厚顶煤,工作面矿震对巷道厚顶煤产生动载作用,易诱发厚顶煤动力失稳和冒顶-冲击复合灾害,亟需探究矿震动载作用下巷道厚顶煤动力失稳机制。【方法】以陕西彬长矿区深部厚顶煤巷道为工程背景,调研分析深部高应力巷道厚顶煤动力失稳特征,数值模拟研究不同静动载作用下巷道厚顶煤多场演化规律,提出矿震诱发高应力巷道厚顶煤动力失稳机制。【结果和结论】结果表明,巷道厚顶煤冒顶区域距回采工作面较远,冒顶后裸露平整顶板,顶板锚索拉断,冒顶区域附近均发生大能量矿震,呈现冒顶-冲击复合灾害现象。随静载增加,巷道围岩裂隙发育深度及变形不断增加;随动载作用时间和动载强度增大,顶煤震动速度、加速度及裂隙发育程度不断增大,顶煤离层量显著增加;顶板锚杆索均位于顶煤裂隙发育区,支护性能大幅降低。静动载作用下巷道厚顶煤累积损伤及离层量不断增大,大能量矿震动载使浅部破碎顶煤震动速度及加速度显著增大,作用在锚索上载荷超过其承载能力,锚索被拉断,浅部破碎煤体以较高速度冒落,诱发厚顶煤动力失稳和冒顶-冲击复合灾害。在此基础上,提出了采用重建厚顶煤主被动支护和加强卸压的深部巷道厚顶煤动力失稳灾害的防治方法。

松软破碎厚顶煤小煤柱巷道围岩控制技术研究

以山寨煤矿3506回风顺槽为工程背景,通过理论分析、数值模拟和现场实践等方法,揭示了松软破碎厚顶煤小煤柱巷道存在围岩变形大、应力高,煤体裂隙发育、围岩稳定性差等特点;提出了“锚杆索高强高阻支护+弱结构卸压”组合围岩控制技术;现场实践结果表明,支护方案优化后,最大顶板下沉量为120.9 mm,最大两帮内缩量为187.4 mm,巷道围岩稳定性得到有效控制,支护效果满足开采生产要求。

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。

工作面尺度和顶煤厚度影响下的放煤规律研究

结合理论分析、数值模拟和工程测试,对顶煤放出规律进行分析,探究顶煤厚度和工作面尺度对放煤结果的影响规律。研究表明:煤岩模型尺度对顶煤运移状态影响较小,对工作面放煤结果的统计分析会产生明显影响;放煤口数目由40增长到100,工作面顶煤回收效率由68%增长到77%,放出煤量和放煤时间明显减少;采用全尺度煤岩模型的放煤模拟更加符合工程实际。随顶煤层厚度由2 m增大到5 m,顶煤回收率由78%逐渐降低到71.6%;总放煤时间非线性增大,各支架放煤波动性增大。

特厚顶煤单双夹矸层巷道开挖围岩变形破坏特征研究

针对特厚顶煤巷道开挖掘进时,单双夹矸层巷道围岩变形破坏特征不明晰的问题,以山西某矿13103工作面进回风巷道为工程背景,运用数值模拟的方法对巷道开挖过程中围岩变形破坏特征进行研究。研究结果表明,应力集中于巷道顶角上部并呈椭圆状分布,顶板最大下沉量出现在巷道中部且随掘进长度呈指数增长;单夹矸层巷道相比双夹矸层巷道应力集中幅度更高,应变更大,顶板破碎更严重。通过对单夹矸层巷道部分锚杆锚索倾斜打设并加长锚索后巷道变形控制效果显著提升,围岩强度得到明显增强,能够保证巷道稳定。

腾晖煤业综放工作面放煤参数设计及应用

针对放顶煤采煤参数对顶煤回收率影响较大的问题,以腾晖煤业2#煤层工程背景,采用理论分析、数值模拟等方法,确定了合理的放煤参数如下:割煤高度为3 m,采放比为1∶1.03,放煤步距为0.8 m,放煤方式为单轮间隔放煤。在2-202工作面进行现场试验,现场监测结果显示,在前述放煤参数条件下,顶煤回收率为89.5%,含矸率为7.6%,前述设计方案合理、可行,可保证工作面安全、高效生产。

不同支架在厚煤层开采过程中的实践与应用

提高煤炭资源采出率和原煤生产效率是衡量煤炭企业高质量发展的重要指标,对厚煤层采用综采放顶煤采煤工艺是当前的唯一选择。分别对两套放顶煤开采装备在地质条件、生产效率、安全管控和顶板管理方面以及支架倒架歪架的事故进行分析,提出了同煤层同地质条件下选择合适的放顶煤开采装备的方向。

特厚煤层综放开采顶煤回收率影响因素及措施

为解决特厚煤层综放开采煤炭资源回收率低的问题,以不连沟煤矿6号煤层为研究对象,分析影响特厚煤层综放开采煤炭资源回收率的因素,得出不连沟6号煤冒放性较好,采放高度合理,顶煤夹矸对放煤有一定影响。放煤工艺参数是影响顶煤回收率的主要因素。针对提高顶煤回收率的关键因素,提出优化放煤方式、放煤步距参数和精益化放煤技术措施,并进行现场应用,优化后F6207工作面顶煤回收率比原来提升了2.7%,应用效果良好。

特厚煤层综放工作面沿空掘巷小煤柱留设与支护研究

为研究特厚煤层综放工作面沿空掘巷留设小煤柱的合理宽度,以塔山煤矿8117工作面回风巷为研究对象,采用理论计算、数值模拟和现场实测相结合的研究方法进行研究。研究表明:相邻工作面采空区稳定后煤体侧向支承应力降低区范围为0~13.7 m,煤柱宽度在8 m以下可确保8117工作面回风巷处于应力降低区,有利于巷道围岩的稳定;煤柱宽度大于8 m时,煤柱内弹性区随煤柱宽度的增加而增大,煤柱中部垂直应力开始超过原岩应力;最终确定采用8 m小煤柱。现场观测表明,留设8 m煤柱时,8117回风巷在掘进和回采阶段巷道两帮移近量和顶底板下沉量较小,煤柱可以有效支撑顶板、控制围岩变形。

厚煤层工作面多种放煤方式的选择

我国大部分煤炭以厚煤层的形式埋藏于地下深处,综放开采是主要的开采工艺方式。在综采过程中,不同的放煤方式对煤层的采出具有重要影响。针对不同放煤方式的影响作用进行仿真分析,可为厚煤层放煤方式的选择提供一定参考。结果表明,单轮间隔放煤具有较好的开采效果,是更适合厚煤层开采的放煤方式。

大倾角厚煤层开采不同采高与放煤步距的影响分析

大倾角厚煤层是我国面临的重要的煤层开采形态,由于煤层的倾角较大,造成开采难度的增加。采用放顶煤综采过程中,不同的采高及放煤步距对顶煤的放出具有重要的影响作用。针对大倾角厚煤层开采过程中,不同采高及放煤步距对顶煤采出率的影响采用PFC仿真模拟的方式进行分析。建立了不同参数的开采模型,对开采过程进行仿真模拟,得到采高为4 m放煤步距为1.6 m(两采一放)的开采工艺为最佳的开采参数,此时顶煤的采出率最高,且具有较好的操作性。

缓倾斜中厚煤层切顶卸压沿空留巷支护应用

以文家坝一矿110606运输巷沿空留巷为工程背景,采用经验公式计算、数值模拟、工程实践、矿压监测等方法,进行沿空留巷预裂爆破切顶卸压,巷内补强支护方案的设计及应用研究。通过理论分析得到预裂切顶钻孔垂高为7.7 m,孔深为8.0 m时,冒落矸石可将采空区充满,设计详细的巷内补强及采空侧挡矸支护方案。运用FLAC^(3D)数值模拟,研究围岩变形与顶板岩层离层量,结果表明,切顶及巷内补强支护方案可行。工程应用期间进行综合矿压监测,留巷围岩变形量在较低水平,巷道围岩整体稳定,锚索承载能力仍有较大富余,可实现沿空巷道的长期安全稳定,取得较好留巷效果。

软煤厚煤层工作面底三角煤高效回收技术

针对软煤厚煤层沿顶掘进顺槽底三角煤丢失严重问题,设计2次落底、2次顶部充填工艺,采用速凝早强高水充填材料,混合浆约15 min失去流动性,30 min完全固化,3 d达最终强度3.8 MPa。效果考察表明:每天一班充填,可以满足5 d的推进需求,实现了底三角煤安全高效回收,实际经济效益达到1610万元,延长了矿井服务年限,缓解了采掘衔接紧张。

智能化开采技术在煤矿的实践与应用

本文建立在智能化采煤工作面的工艺研究和放顶煤开采工艺的理论基础上,结合当前国内先进的智能放顶煤开采工艺,以新疆某矿智能综放工作面开采为研究对象,对该采煤工作面在中山区侏罗纪煤层群和倾斜特厚煤层的智能化开采工艺、智能综放设备应用和功能发挥、智能化开采技术以及智能放顶煤开采过程中的煤炭资源回收等方面开展综合性实践研究。得出,智能化开采技术在开采过程中在减人、提效、增安方面取得效果,在提高资源回收率方面所取得的经验做法以及下一步需要持续改进的方向。

特厚煤层超大采高综采工作面冒顶防治技术

在煤矿开采过程中,伴随着开采装备水平的提升,为了提高煤炭资源回收率,一次采全高的超大采高综采工作面占据比例逐年增加,冒顶片帮的几率也随之增加。本文以上湾煤矿12403综采工作面冒顶事故为背景,从注高分子材料、铺设假顶和处理大块矸石三个方面介绍了超大采高工作面冒顶防治技术,为超大采高综采工作面面临的冒顶问题提供了明确、有效的解决措施。

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.