综放工作面端头滞后放顶煤技术研究及应用

doi:10. 11799/ ce202507001

摘要/Abstract

摘要：

针对厚煤层综放开采过程中回采巷道顶煤无法回收以及过渡支架顶煤损失这一难题，综合运用理论分析、数值模拟和现场应用等研究方法，基于端头顶板变形特征，提出了一种安全回收端头顶煤的方法——综放工作面端头滞后放顶煤技术。该方法将具备放煤功能的端头放煤支架向采空区方向滞后工作面支架2~3m布置，同时延长转载机和后刮板运输机至端头和端尾放煤支架尾梁下方，并选用具备放煤功能的过渡支架，利用原工作面的运煤设备，回收工作面的顶煤和回采巷道的顶煤；同时还给出了一系列经实践检验有效的诸多端头顶煤助冒放技术，如退锚、破网、气爆致裂、静态膨胀致裂等；该综放工作面端头滞后放顶煤技术在三元煤业的应用效果显著。结果显示，工作面每回采1m可多回收约72t端头顶煤资源，工作面的采出率提高了2.5%，实现了回采巷道顶煤及过渡支架顶煤的安全高效回收。

关键词: 回采巷道 , 过渡支架 , 端头顶煤 , 端头放顶煤 , 放煤支架

Abstract:

To address the technical challenges of end-zone top coal recovery which is loacted over roadwagys and transition supports in thick-seam fully mechanized top coal caving mining face, based on the deformation characteristics of the roof strata in end-zone, a technology of end-zone top coal recovery through lagging end-zone coal caving supports in a fully mechanized top coal caving face is proposed by combining theoretical analysis, numerical simulation and field application. The caving-capable supports in the end zone are arranged 2–3m lagging behind the working face supports torward the direction of goaf, and the transfer machine and the rear scraper conveyor are extended to the end of the coal caving supports in end-zone of the working face. At the same time, the transition supports with coal caving function are adopted, and the top coal of the whole working face and the top coal of the mining roadways can be recovered by using the coal transportation equipment of the original working face. Multiple validated top coal fracturing technologies have been implemented, including anchor withdrawing, mesh cutting, gas explosion fracturing, and static expansion fracturing. Applicaton of the technology of recoverying end-zone top coal through lagging end-zone coal caving supports in a fully mechanized top coal caving face in Sanyuan coal mine shows that about 72 tons of top coal resources can be additonnally recovered for every 1m mining, and the recovery rate of the working face is increased by 2.5%. The safe and efficient recovery of the top coal of the mining roadways and the top coal of the transition support has not only achieved remarkable economic benefits, but also promoted the safe, efficient and sustainable mining of the mine.

中图分类号:

TD823

崔永青, 赵宝友.

综放工作面端头滞后放顶煤技术研究及应用 [J]. 煤炭工程, 2025, 57(7): 1-7.

参考文献

[1]于斌, 匡铁军, 杨敬轩, 等. 特厚煤层开采坚硬顶板覆岩结构及其演化特征分析[J]. 煤炭科学技术, 2023, 51(1): 95-104.
YU Bin, KUANG Tiejun, YANG Jingxuan, et al. Analysis of overburden structure and evolution characte-ristics of hard roof mining in extremely thick coal seam[J]. Coal Science and Technology, 2023,51(1): 95-104.
[2]王国法, 庞义辉, 许永祥, 等. 厚煤层智能绿色高效开采技术与装备研发进展[J]. 采矿与安全工程学报, 2023, 40(5): 882-893.
WANG Guofa, PANG Yihui, XU Yongxiang, et al. Development of intelligent green and efficient miningtechnology and equipment for thick coal seam[J]. Coal Science and Technology, 2023, 40(5): 882-893.
[3]宋选民, 朱德福, 王仲伦, 等. 我国煤矿综放开采40年：理论与技术装备研究进展[J]. 煤炭科学技术, 2021, 49(3): 1-29.
SONG Xuanmin, ZHU Defu, WANG Zhonglun, et al. Advances on longwall fully-mechanized top-coal caving mining technology in China during past 40 years: theory, equipment and approach[J]. Coal Science and Technology, 2021, 49(3): 1-29.
[4]王家臣. 我国综放开采40年及展望[J]. 煤炭学报, 2023, 48(1): 83-99.
WANG jiachen. 40 years development and prospect of longwall top coal caving in China [J]. Journal of ChinaCoal Society, 2023, 48(1): 83-99.
[5]孟宪锐, 吴昊天, 王国斌. 我国厚煤层采煤技术的发展及采煤方法的选择[J]. 煤炭工程, 2014, 46(10): 43-47.
MENG Xianrui, WU Haotian, WANG Guobin. Development and method selection of thick coal seam mining technology in China[J]. Coal Engineering, 2014, 46(10): 43-47.
[6]王国法, 庞义辉, 马英. 特厚煤层大采高综放自动化开采技术与装备[J]. 煤炭工程, 2018, 50(1):1-6.
WANG Guofa, PANG Yihui, MA Ying. Automated mining technology and equipment for fully-mechanized caving mining with large mining height in extra-thick coal seam[J]. Coal Engineering, 2018, 50(1):1-6.
[7]金太, 李伟, 孔庆康, 等. 鲍店煤矿综放工作面端头放顶煤实践[J]. 煤炭科学技术, 1998, 26(3): 38-40.
JIN Tai, LI Wei, KONG Qingkang, et al. Practice of top coal caving at the end of fully mechanized caving face in Baodian Coal Mine[J]. Coal Science and Technology, 1998, 28(3): 38-40.
[8]张亚宁, 解立赫, 张岱岳. 综放工作面端头放煤研究进展与展望[J]. 煤炭工程, 2017, 49(10): 35-37,42.
ZHANG Yaning, XIE Lihe, ZHANG Daiyue. Research progress and prospect of coal caving at the ends of fully mechanized top-coal caving face[J]. Coal Engineering, 2017, 49(10): 35-37,42.
[9]吕世宏, 张双林, 张拴玉. 端头支架在急倾斜特厚煤层综采放顶煤工作面的应用与改进[J]. 煤矿安全, 2002, (10): 36-37.
Application and improvement of end support in fully mechanized top coal caving face in steeply inclined thick coal seam[J]. Safety in Coal Mines, 2002, (10): 36-37.
[10]梁和平, 章之燕. 开滦矿区综采放顶煤工艺煤炭采出率的分析[J]. 煤炭科学技术, 2008, 36(7): 13-15.
LIANG Heping, ZHANG Zhiyan. Analysis on coal mining rate of fully mechanized top coal caving mining in Kailuan Mining Area[J]. Coal Science and Technology, 2008, 36(7): 13-15.
[11]马运峰, 孔庆康, 姜瑞, 等. 综放工作面运输巷端头放顶煤支架的研究与应用[J]. 矿山机械, 2011, 39(1): 12-16.
MA Yunfeng, KONG Qingkang, JIANG Rui, et al. Study and application of sublevel caving supports at ends of transportation tunnels on fully-mechanized caving faces[J]. Mining & Processing Equipment, 2011, 39(1): 12-16.
[12]赵景礼, 李报. 提高综放煤炭回收率的研究—兼论错层位巷道布置系统[J]. 辽宁工程技术大学学报(自然科学版), 1998, 17(3): 237-239.
ZHAO Jingli, LI Bao. A Study on raising the recovery ratio of fully-mechanized coal talking about stagger-position-roadway-arrangement system[J]. Journal of Liaoning Technical University(Natural Science), 1998, 17(3): 237-239.
[13]王树岗, 赵景礼, 刘斌慧. 综放工作面错层位立体化巷道布置技术研究及应用[J]. 煤炭工程, 2016, 48(7):1-4.
WANG Shugang, ZHAO Jingli, LIU Binhui. Research and application of stagger three-dimensional roadway arrangement in fully mechanized top coal caving face[J]. Coal Engineering, 2016, 48(7):1-4.
[14]王志强, 苏越, 苏泽华, 等. 外错式区段间相邻巷道锚杆联合支护作用机理研究[J]. 采矿与安全工程学报, 2021, 38(1): 58-67.
WANG Zhiqiang, SU Yue, SU Zehua, et al. Mechanism of combined support by bolts for adjacent roadways in the external-staggered split-level panel layout[J]. Journal of Mining & Safety Engineering, 2021, 38(1): 58-67.
[15]杜云楼, 夏龙, 闫耀飞. 回风顺槽沿顶掘进在贵石沟矿井综放工作面的应用[J]. 煤炭技术, 2016, 35(12): 84-86.
DU Yunlou, XIA Long, YAN Yaofei. Application of return airway excavating along roof of fully mechanized top coal caving face in Guishigou Coal Mine[J]. Coal Technology, 2016, 35(12): 84-86.
[16]钱鸣高, 石平五, 许家林. 矿山压力与岩层控制[M]. 徐州: 中国矿业大学出版社, 2010.
[17]张福范. 均布荷载下悬臂矩形板的弯曲[J]. 应用数学和力学, 1980, 1(3): 349-362.
ZHANG Fufan. Bending ofuniformly loaded cantilever rectangular plates[J]. Applied Mathematics and Mechanics, 1980, 1(3): 349-362
[18]张福范. 两相邻边固定两相邻边自由的矩形板[J]. 固体力学学报, 1981, 2(4): 491-502.
ZHANG Fufan. Rectangular plates with two adjacent edges clamped and other two edges free[J]. Chinese journal of solid mechanics, 1981, 2(4): 491-502.
[19]王崇勋, 荚逸晨, 赵宝友. 回采巷道顶煤二氧化碳气爆致裂冒放技术[J]. 煤炭工程, 2023, 55(8): 63-67.
WANG Chongxun, JE Yichen, ZHAO Baoyou. Top coal caving enhancement by CO2 gas shock technique in coal mine entry[J]. Coal Engineering, 2023, 55(8): 63-67.
[20]史达, 高明星, 赵宝友. 高瓦斯综放面开切眼架前膨胀预裂坚硬顶板切顶技术研究[J]. 煤炭技术, 2024, 43(6): 64-68.
SHI Da, GAO Mingxing, ZHAO Baoyou. Expansion pre-splitting technique in front of open cut for hard roof cutting in high gas fully-mechanized caving face[J]. Coal Technology, 2024, 43(6): 64-68.