Back-and-forth mining for hard and thick coal seams—research about the mining technology for fully mechanized caving working face of Datong Mine

The article introduced the key technology, mining process, and back-and-forth mining method for the caving working face of hard-thick coal seams in Datong mine, and researched this innovations process, optimized the systemic design and working face out-play, tried to perfect the caving mining technology of hard-thick coal seams further.

Ground pressure and overlying strata structure for a repeated mining face of residual coal after room and pillar mining

To investigate the abnormal ground pressures and roof control problem in fully mechanized repeated mining of residual coal after room and pillar mining, the roof fracture structural model and mechanical model were developed using numerical simulation and theoretical analysis. The roof fracture characteristics of a repeated mining face were revealed and the ground pressure law and roof supporting condi- tions of the repeated mining face were obtained. The results indicate that when the repeated mining face passes the residual pillars, the sudden instability causes fracturing in the main roof above the old goal and forms an extra-large rock block above the mining face. A relatively stable ＂Voussoir beam＂ structure is formed after the advance fracturing of the main roof. When the repeated mining face passes the old goaf, as the large rock block revolves and touches gangue, the rock block will break secondarily under overburden rock loads. An example calculation was performed involving an integrated mine in Shanxi province, results showed that minimum working resistance values of support determined to be reason- able were respectively 11,412 kN and 10,743 kN when repeated mining face passed through residual pillar and goaf. On-site ground pressure monitoring results indicated that the mechanical model and support resistance calculation were reasonable.

Systematic principles of surrounding rock control in longwall mining within thick coal seams

Effective surrounding rock control is a prerequisite for realizing safe mining in underground coal mines.In the past three decades, longwall top-coal caving mining(LTCC) and single pass large height longwall mining(SPLL) found expanded usage in extracting thick coal seams in China. The two mining methods lead to large void space left behind the working face, which increases the difficulty in ground control.Longwall face failure is a common problem in both LTCC and SPLL mining. Such failure is conventionally attributed to low strength and high fracture intensity of the coal seam. However, the stiffness of main components included in the surrounding rock system also greatly influences longwall face stability.Correspondingly, surrounding rock system is developed for LTCC and SPLL faces in this paper. The conditions for simultaneous balance of roof structure and longwall face are put forward by taking the stiffness of coal seam, roof strata and hydraulic support into account. The safety factor of the longwall face is defined as the ratio between the ultimate bearing capacity and actual load imposed on the coal wall.The influences provided by coal strength, coal stiffness, roof stiffness, and hydraulic support stiffness,as well as the movement of roof structure are analyzed. Finally, the key elements dominating longwall face stability are identified for improving surrounding rock control effectiveness in LTCC and SPLL faces.

Research on Feasibility of Top-Coal Caving Based on Neural Network Technique

Based on the neural network technique, this paper proposes a BP neural network model which integrates geological factors which affect top coal caving in a comprehensive index. The index of top coal caving may be used to forecast the mining cost of working faces, which shows the model’s potential prospect of applications.

Mating model on production capacity for the system of cutting coal and drawing top-coal in FMMSC

Being a safe and highly-efficient mining method, fully mechanized mining with sublevel caving （FMMSC） was extensively employed in Chinese coal mines with thick seam. In order to make drawing top-coal furthest to parallel work with shearer cutting coal, decrease failure ratio of rear scraper conveyor and increase safe production capacity of equipments, based on production technology, set up the mating model of safe production capacity of equipments for the system of drawing top-coal and shearer cutting coal in coal face with sublevel caving. It is mean capability of drawing top-coal adapted to the capability of shearer cutting coal in a working circle in the coal face that was deduced. The type selection of equipment of rear scraper conveyor can be tackled with this mating model. The model was applied in FMMSC in Yangcun Coal Mine, Yima Coal Group of China. With the mating light-equipments, the coal output in coal face attained 1.05 Mt in 2004. It gained better technical-economic benefit.

综放工作面围岩控制与智能化放煤技术现状及展望

分析了厚及特厚煤层智能化综放工作面围岩控制技术与智能化放顶煤技术发展现状及存在的问题,从巷道围岩高效支护、工作面超前支护、坚硬特厚顶煤冒放性、液压支架位姿监测及智能化放顶煤5个方面提出了工程实际需求。针对综放工作面实现安全、高效、智能化开采存在的技术难题与工程需求,对综放工作面围岩控制技术、智能化放煤技术进行了研究:构建了坚硬特厚煤层顶煤悬臂梁力学模型,研发了提高顶煤冒放性及放出率关键技术,实现了坚硬特厚煤层超大采高综放开采;研发了单元式超前液压支架顶梁可旋转自复位装置,实现了液压支架顶梁根据巷道顶板倾斜角度自动旋转支护,有效提高了单元式超前液压支架对巷道顶底板的适应性;提出了采用巷道支护液压支架替代传统锚网支护结构的思路,具有支护效率高、成本低、节省工作面超前支护等优点;开发了基于立柱与尾梁千斤顶行程的综放液压支架支护姿态监测装置与算法,提高了液压支架支护姿态解算效率与精度;提出了基于透明地质模型、煤量监测装置与煤矸识别装置融合的智能放煤控制方法,可有效解决多夹矸层特厚顶煤智能化放煤技术难题。提出智能地质保障技术、机器视觉精准测量与智能感知技术、综放工作面设备智能精准自适应控制技术、综放工作面数字孪生技术等是智能化综放开采技术与装备的发展趋势。

两次采动影响下小煤柱巷道切顶卸压围岩控制技术

为解决多次采动影响下留小煤柱巷道矿压显现剧烈、围岩变形量大的问题,提出了“切顶卸压+顶、帮锚索补强”联合控制技术。以贾家沟煤矿10115运输巷为工程背景,分析了切顶卸压位置、高度与巷道围岩垂直应力分布的关系,给出切顶卸压关键参数,并研究了留小煤柱巷道在切顶卸压后受两次采动影响下的矿压显现规律。结果表明:切顶卸压后,煤柱上的应力峰值随切顶深度的增加呈指数降低;10115运输巷在邻近工作面一次采动过程中巷道围岩变形依次呈现出无变形、缓慢变形、快速变形和围岩稳定的变化规律,本工作面二次采动过程中巷道围岩变形依次呈现出明显变形和剧烈变形的规律;巷道围岩在受二次采动影响时变形更加剧烈,巷道变形量为一次采动时的3.0~7.5倍。

煤矿大倾角综放工作面采煤参数及采煤工艺优化分析

以A煤矿26514工作面为例,介绍了一种基于有限元分析的煤矿大倾角综放工作面采煤参数及采煤工艺优化方法。该方法根据煤矿大倾角综放工作面参数构建相应的有限元模型,通过有限元模型的分析寻找现有工作面采煤参数与采煤工艺的缺陷,进而以此为基础制定工作面采煤参数与采煤工艺优化方案。研究对大倾角综放工作面的开采具有重要意义。

煤矿工作面安全状态评价指标赋权策略研究

煤矿工作面安全状态精准评价可促进矿井安全管理水平和防灾抗灾能力提升。以CH_(4)浓度、CO_(2)浓度、CO浓度、O_(2)浓度、温度、风速6种工作面环境监测数据为评价指标,对工作面安全状态进行评价分析。为合理确定评价指标的权重,提高安全评价结果的准确性,采用模糊层次分析法(FAHP)计算评价指标的主观权重、G-GRITIC法计算指标的客观权重,通过基于改进博弈论(IGT)的组合赋权法将主观权重与客观权重结合,得出评价指标的组合权重,解决了决策过程中主客观信息不一致性问题。基于陕西黄陵二号煤矿有限公司209综采工作面安全监控系统采集数据,对基于IGT的组合赋权法进行实验验证,结果表明该方法有效避免了线性加权法、平均加权法的主观判断性,优化了基于博弈论(GT)的组合赋权法的偏差结果,得到的评价指标更加合理,可获得更加准确的煤矿工作面安全状态评价结果。

工作面停采煤柱宽度的确定与实践

燕子山矿采用宽煤柱方式护巷,煤柱宽度约60 m,造成资源的严重浪费。通过对回风巷的受力变化规律进行监测分析,得出工作面回采对巷道压力影响的临界距离为35 m。以此为依据,在综合考虑8210工作面特殊性的基础上,分析得出该工作面最佳停采煤柱宽度为38~45 m。为检验8210工作面煤柱宽度,该矿在回风大巷开展了顶板钻孔窥视工作,检测顶板煤层回采期间和停采后的变化情况,窥视检测结果表明,工作面留设38~45 m煤柱宽度能够保证巷道围岩的稳定性,是安全可靠的。

三软特厚煤层综放工作面瓦斯综合治理

三软煤层(软的顶板岩层、软的主采煤层和软的煤层底板岩层)瓦斯治理是煤矿安全面临的难题之一。焦家寨煤矿52105工作面目前开采的煤层属于三软煤层,在瓦斯抽采过程中抽采钻孔不但塌孔严重,而且施工困难。针对这种情况,采用了瓦斯综合治理模式,将本煤层瓦斯抽放和穿层钻孔抽放相结合。重点分析了瓦斯治理的方案,主要是钻孔的布置参数。研究结果表明,在进行综合治理后,上隅角瓦斯体积分数为0.65%左右,回风流瓦斯体积分数为0.32%左右,确保了工作面的安全生产。

综放工作面小煤柱沿空掘巷煤柱尺寸留设研究

为合理留设综放工作面沿空掘巷煤柱,以山西某矿E4102-1工作面运输顺槽煤柱留设工程概况为例,通过进行调研分析与进行数值模拟分析,并结合工业性试验,得出窄煤柱沿空掘巷技术目前已相对较成熟,可把煤柱尺寸留设为5 m至8 m之间;通过对几种煤柱尺寸下的巷道围岩破坏状况进行数值模拟分析,得出该工作面巷道留设5 m宽的煤柱时,该巷道矿压不会出现明显显现,巷道变形量相对较小,巷道顶板也相对较稳定,能很好的满足矿井安全生产需求,更好地保障矿井安全生产。

大采高工作面末采深孔预注浆加固技术

针对寺河矿大采高工作面末采期间煤壁片帮冒顶问题,对寺河矿5303工作面超前支承压力分布规律、深孔预注浆加固机理、合理注浆加固时机进行了深入分析,通过优选注浆材料及工艺,提出了超前深孔预注浆、撤架通道预注浆、工作面浅孔注浆耦合加固方案。实践表明,深孔预注浆加固方案的应用效果良好,末采期间煤帮基本保持平整,未出现大范围、大深度的片帮现象,工作面最后15 m仅用3 d时间便顺利回采完成,有效确保了支架回撤期间生产的安全性。

沿顶板布置回采巷道倾斜长臂放顶煤工作面开采技术研究

隆华煤业15#煤层煤质酥软,15102胶带顺槽沿煤层底板布置时,存在托顶煤困难,随掘随冒的现象,造成巷道超高、掘进效率降低,且形成高冒区造成瓦斯积聚,存在安全隐患。15102轨道顺槽采用沿顶掘进解决了托煤困难,随掘随冒现象,实现了快速掘进,从采煤工艺的改革、通风和生产、瓦斯治理等方面综合考虑,具有明显的安全和经济效益。

综放工作面采后覆岩移动规律及离层空间发展形态分析

综放工作面大规模开采后容易造成显著的地表沉陷等相关问题,为进一步探究综放工作面采后覆岩运动规律及离层空间发育形态,结合山西晋煤集团晋圣坡底煤业有限公司矿区工程实际情况,以3106工作面为工程背景,采用数值模拟和现场实测两种方法进行综合研究。结果表明,在工作面回采的第一阶段,离层一般可以达到煤层开采厚度的0.31倍,最大可以达到0.58倍的开采厚度;第二阶段分离缝宽度较窄,分离量较小,离层从起裂到达到最大值一般需要20~30 d,相当于工作面推进70~100 m,对应层位高度为200 m。

松软厚煤层孤岛工作面回采巷道支护技术研究

受滑动地质构造影响,芦沟煤矿煤层厚度大且极为松软,工作面巷道维护一直十分困难。针对芦沟煤矿21采区孤岛煤柱工作面特殊地质条件,模拟分析了工作面开采后煤柱支承压力的分布规律。模拟结果表明,支承压力峰值位于距采空区边缘11 m处,峰值应力集中系数约1.8;采空区边缘支承压力平均值约为7.23 MPa。从保护巷道角度出发,将孤岛工作面两巷沿采空区边缘布置,设计了孤岛工作面回采巷道高强柔性锚棚支护方案,工作面回采期间巷道围岩变形得到了有效控制。

采动影响巷道支护方案设计及效果

为减少松软煤层围岩巷道受采动影响的破坏,提高煤层开采的安全性,以某矿为对象,分析该矿松软煤层在采动影响下围岩的变化规律,设计巷道联合支护技术为“锚网喷+锚索梁+注浆”。与无支护技术相比,经联合支护优化后,该矿巷道顶底板及两帮变形量分别降低68.5%、50%、61%,降幅明显,表明该联合支护技术能有效控制围岩变形,支护效果好。

华亭煤矿综放工作面末采阶段柔性网支护效果分析

为确保华亭煤矿综放工作面安全高效回撤,250107-1综放工作面末采阶段采用高强聚酯纤维柔性网代替金属网铺顶。主要介绍柔性网使用前运网、挂网相关准备工作以及柔性网施工工艺,并根据250107-1综放工作面柔性网工程实践,分析柔性网在工作面末采阶段的突出优势与存在的问题,并针对柔性网应用过程中存在的问题,提出优化柔性网尺寸、配合金属网挂网技术、加强放煤与割煤工艺管理的保障技术措施。

三软煤层条件下工作面浅孔注水钻孔设置方式探索

针对告成煤矿三软煤层生产过程中,煤尘比较突出、劳动作业环境恶劣和容易诱发煤尘事故等问题,在23041综采工作面进行了工作面浅孔注水伪斜钻孔设置方法的试验和探索,并将该方法与现用的注水垂直钻孔设置方法进行了对比试验。实践证明,工作面浅孔注水伪斜钻孔设置方法可减少综采工作面生产过程中粉尘的产生量,对促进安全生产具有重要意义。

综放端头支架与后部输送机配套形式及空间探讨

智能化无人开采是实现煤矿安全高效开采的技术途径,各种设备的自动化及相互间的配套影响着工作面的智能化程度,合理的配套形式及空间是提高开采自动化率的保障。随着工作面开采设备能力的提高,相关配套设备特别是刮板输送机两端的驱动部体积和占用空间不断增大,受设备配套和设备尺寸制约,给工作面的自动化运行与控制带来挑战。对于综放工作面,两端头的端头支架与后部输送机的配套非常关键。为了解决端头支架尾柱与后部输送机电动机间相对位置观察不便、难于控制、发生碰撞损坏电动机、需要人工干预的痛点,通过端头支架底座与后部输送机间限位装置的研究和毫米波雷达的应用,从机械、控制、监测等方面形成了综放工作面两端头后部狭窄空间的设备安全解决方案,此方案的实施,取得了较好的应用效果。