厚基岩下工作面端头弧形三角区演化规律与治理

doi:10. 11799/ ce202507011

摘要/Abstract

摘要：

厚基岩工作面回采期间易出现端头弧形三角区大面积悬顶现象，对煤矿安全生产构成威胁。为揭示该弧形三角区的形成机理及演化规律，以黄玉川煤矿12407工作面为研究对象，采用理论分析、实验室试验以及数值模拟相结合的方法开展研究。结果表明：受顶板岩石高强度特性影响，顶板发生“O—X”型破断后，工作面两端头坚硬顶板难以垮落，进而形成大面积端头悬顶并构成弧形三角区；理论计算得出该工作面端头弧形三角区的悬顶距离为20.1 m，与现场观测结果高度吻合。随着工作面推进，端头弧形三角区的几何形态仅发生微小变化。基于此，提出现场水力压裂治理方案：在巷道正帮肩角布置仰角 40°、倾角45°、深度30m、间距20m的钻孔，同时联合在巷道负帮布置仰角40°、倾角0°、深度30 m、间距20m 的钻孔。现场应用结果显示，治理后悬顶几何结构沿工作面推进平行方向尺寸减小60%，沿垂直方向尺寸减小73.5%。

关键词:

厚基岩 , 端头弧形三角区 , 水力压裂 , 悬顶治理 , 顶板破断

Abstract:

Thick bedrock working face is prone to produce the phenomenon of large overhanging area of the arc-shaped triangle at the end of the working face during the mining period, which is prone to produce the accident of large-area coming pressure on the roof plate and affects the safe production of coal mines. In order to analyze the mechanism and evolution law of the formation of the arc-shaped triangle at the end of the working face, we take the working face of 12407 of Huangyuichuan Coal Mine as the research background and focus on the problem of large overhanging area of the arc-shaped triangle at the end of the working face during the mining process in the gum transporting and wind-returning chutes, through the combination of theoretical analysis, laboratory test and numerical simulation. In order to solve the problem of large overhanging roof area in the working face of 12407 working face, through theoretical analysis, laboratory test and numerical simulation, we analyzed the formation mechanism of 12407 working face arc triangle, studied the evolution law of 12407 working face arc triangle in the process of mining, and put forward the management plan of large overhanging roof area in 12407 working face arc triangle of Huangyuchuan Coal Mine. Research results show that: due to the roof plate "O-X" broken, the roof plate rock strength is larger, the working face two ends of the location of the hard roof plate is difficult to collapse, easy to produce the working face roof end of a large area of overhanging, the formation of the end of the arc-shaped triangle, theoretical calculations of the Huangyuchuan coal mine 12407 working face end of the arc-shaped triangle Theoretical calculation shows that the overhanging distance of the triangle is 20.1m; by analyzing the damage characteristics of the roof plate in the air-mining area during the advancement of the working face, it is concluded that with the advancement of the working face, the geometrical form of the working face's end arc-shaped triangle is gradually reduced, but the magnitude of the reduction is relatively small, and there is still a safety hazard of the end-end large-scale overhanging roof, and the Huangyu-Chuan coal mine 12407 working face's end-end arc-shaped triangle management plan is proposed to manage the overhanging roof in the field. Along the parallel direction of the working face from the original 20m reduced to 5.3m, along the vertical direction of the working face from the original 15m reduced to 6m.

中图分类号:

TD327. 2

杨喜君, 曾繁炜, 宫志强.

厚基岩下工作面端头弧形三角区演化规律与治理 [J]. 煤炭工程, 2025, 57(7): 74-80.

参考文献

[1]王佟, 刘峰, 赵欣, 等.双碳”背景下我国煤炭资源保障能力与勘查方向的思考[J].煤炭科学技术, 2023, 51(12):1-8 [2]WANG Tong, LIU Feng, ZHAO Xin, et al.Reflections on China's coal resource guarantee capacity and exploration direction under the background of "double carbon"[J].Coal Science and Technology, 2023, 51(12):1-8 [3] 梁运培, 李其罡, 黄旭超, 等.基于颗粒流的倾斜厚煤层坚硬顶板运动失稳规律及水力弱化参数研究[J/OL][J].岩石力学与工程学报, , 1-11:- [4]Liang Yunpei, Li Qigang, Huang Xuchao, et al.Study on the instability law and hydraulic weakening parameter of hard roof movement in inclined thick coal seam based on particle flow[J/OL]. [J].Journal of Rock Mechanics and Engineering, , 1-11:- [5]钱鸣高, 许家林.煤炭开采与岩层运动[J].煤炭学报, 2019, 44(04):973-984 [6]Qian Minggao, Xu Jialin.Coal mining and rock movement[J].Journal of Coal, 2019, 44(04):973-984 [7]钱鸣高, 许家林, 王家臣.再论煤炭的科学开采[J].煤炭学报, 2018, 43(01):1-13 [8]Qian Minggao, Xu Jialin, Wang Jiachen.Revisiting the scientific mining of coal[J].Journal of Coal, 2018, 43(01):1-13 [9]王家臣, 许家林, 杨胜利, 等.煤矿采场岩层运动与控制研究进展——纪念钱鸣高院士“砌体梁”理论年[J].煤炭科学技术, 2023, 51(01):80-94 [10]Wang Jiachen, Xu Jialin, Yang Shengli, et al.Progress of research on rock movement and control in coal mine quarries--Commemorating 40 years of academician Qian Minggao's "masonry beam" theory[J].Coal Science and Technology, 2023, 51(01):80-94 [11] 缪协兴, 陈荣华, 浦海, 等.采场覆岩厚关键层破断与冒落规律分析[J].岩石力学与工程学报, 2005, (08):1289-1295 [12]Xiexing Miao, Ronghua Chen, Hai Pu, et al.Analysis of breakage and fall pattern of thick key layer in quarry overburden[J]. Journal of Rock Mechanics and Engineering, 2005, (08):1289-1295 [13] 于斌.大同矿区特厚煤层综放开采强矿压显现机理及顶板控制研究[D].中国矿业大学, 2014. [14]YU Bin.Research on the mechanism of strong mineral pressure and roof control in comprehensive mining of extra-thick coal seams in Datong mine area[D]. China University of Mining and Technology, 2014. [15]李楠.综采工作面厚硬砂岩顶板深孔爆破预裂卸压技术与应用[J].煤炭技术, 2022, 41(07):143-147 [16]Li N.Application of deep-hole blasting technology for decompression of thick and hard sandstone roof in comprehensive mining face[J].Coal Technology, 2022, 41(07):143-147 [17]徐雪战.低透气煤层超高压水力割缝与水力压裂联合增透技术[J].煤炭科学技术, 2020, 48(07):311-317 [18]XU Xuezhang.Combined penetration enhancement technology of ultrahigh-pressure hydraulic slitting and hydraulic fracturing in low permeability coal seams[J].Coal Science and Technology, 2020, 48(07):311-317 [19]赵善坤.深孔顶板预裂爆破与定向水压致裂防冲适用性对比分析[J].采矿与安全工程学报, 2021, 38(04):706-719 [20]Zhao Shankun.Comparative analysis of the applicability of deep-hole roof pre-cracking blasting and directional hydraulic fracturing to prevent impacts[J].Journal of Mining and Safety Engineering, 2021, 38(04):706-719 [21]段宏飞, 杨强.水力压裂控制坚硬顶板室内试验及现场测试[J].煤矿安全, 2019, 50(07):26-30 [22]Duan Hongfei, Yang Qiang.Indoor test and field test of hydraulic fracturing to control hard top plate[J].Coal Mine Safety, 2019, 50(07):26-30 [23]梁运培, 李其罡, 黄旭超, 等.基于颗粒流的倾斜厚煤层坚硬顶板运动失稳规律及水力弱化参数研究[J/OL][J].岩石力学与工程学报, , 1-11:- [24]Liang Yunpei, Li Qigang, Huang Xuchao, et al.Study on the instability law and hydraulic weakening parameter of hard roof movement in inclined thick coal seam based on particle flow[J/OL][J]. Journal of Rock Mechanics and Engineering, , 1-11:- [25]林志斌, 李亚超, 吴疆宇, 等.水力压裂对末采矿压显现规律的影响研究[J].采矿与安全工程学报, 2023, 40(04):714-721 [26]LIN Zhi-Bin, LI Ya-Chao, WU Jiang-Yu, et al.Study on the effect of hydraulic fracturing on the pressure emergence pattern of end-mining[J].Journal of Mining and Safety Engineering, 2023, 40(04):714-721 [27]王玉军, 李晓旭, 冀瑞锋, 等.综放工作面强动压巷道围岩综合控制技术研究与应用[J].煤炭工程, 2023, 55(08):51-57 [28]WANG Yujun, LI Xiaoxu, JI Rufeng, et al.Research and application of comprehensive control technology for the peripheral rock of strong dynamic pressure roadway in general-purpose working face[J].Coal Engineering, 2023, 55(08):51-57 [29]司瑞江, 李飞鹏, 赵璐璐, 等.区段大煤柱水力压裂切顶护巷技术研究[J].煤炭科学技术, 2020, 48(07):282-287 [30]SI Ruijiang, LI Feipeng, ZHAO Lulu, et al.Hydraulic fracturing of large coal column in section to cut the roof and protect the roadway[J].Coal Science and Technology, 2020, 48(07):282-287 [31] 秦乐尧, 张连勇.综放工作面端头顶板结构与稳定性研究[J].煤矿现代化, 2000, (06):14-16 [32]QIN Leyao, ZHANG Lianyong.Research on the structure and stability of the roof plate at the end of the working face[J]. Coal mine modernization, 2000, (06):14-16 [33]李奥立, 王沉, 苟仁涛, 等.坚硬顶板工作面支架前方切顶卸压技术研究[J].矿业研究与开发, 2024, 44(05):85-91 [34]Li Aoli, Wang Shen, Gou Rentao, et al.Research on the technology of cutting top and unloading pressure in front of the support of hard-roofed working face[J].Mining Research and Development, 2024, 44(05):85-91 [35] 林榆昆, 刘江伟, 刘耀友.迎采掘进巷道水力切顶关键部位对顶板断裂行为的影响[J/OL].:.[J].煤炭学报, , 1-15:- [36]LIN Yukun, LIU Jiangwei, LIU Yaoyou.Influence of key parts of hydraulic roof cutting on roof fracture behavior in Yingmai digging roadway[J/OL][J]. Journal of Coal, , 1-15:- [37] 张永将, 季飞, 赵同彬, 等.临空巷道坚硬顶板水力割缝-压裂联合控顶卸压技术研究[J/OL][J].煤炭学报, , 1-13:- [38]ZHANG Yonggong, JI Fei, ZHAO Tongbin, et al.Research on joint roof control and pressure relief technology of hydraulic slit-fracture on hard roof plate in open roadway[J/OL].[J].Coal Journal, , 1-13:- [39]季飞.临空巷道煤柱割缝爆破切顶联合卸压技术研究[J].煤炭工程, 2024, 56(03):66-74 [40]Ji Fei.Research on joint decompression technology for cutting seam and blasting top cutting of coal pillar in open roadway[J].Coal Engineering, 2024, 56(03):66-74