近距离采空区下煤层开采矿压显现特征研究
Study on pressure characteristics of coal seam under close mined-out area
-
摘要: 以湘桥煤矿10#煤层开采为工程背景,对上覆采空区的底板破坏情况以及下伏煤层开采的顶板变形进行了理论分析,采用UDEC数值模拟软件对比分析了单一煤层开采与近距离采空区下煤层开采的矿压显现规律。结果表明:相较于单一煤层开采,近距离采空区下煤层开采支承压力应力集中程度更高,其超前支承压力强度更大;同时,由于近距离采空区下煤层开采属于重复采动,下煤层顶板岩层破坏较单一煤层开采更为严重,采场支护强度设计必须考虑上部采空区的影响。因此,在进行近距离采空区下煤层开采时必须采取加强下伏煤层开采超前支护、提高采场液压支架支护强度等措施,以保证近距离采空区下煤层开采顶板的有效管理和安全回采。
-
关键词:
- 近距离采空区下煤层开采 /
- 底板破坏深度 /
- 覆岩破断 /
- 采动应力分布 /
- 工作面支护
Abstract: The 10# coal seam of Xiangqiao Coal Mine are taken as the engineering background, the failure of the floor of the overlying goaf and the deformation of the roof strata of the underlying coal seam were analyzed theoretically, and the coal pressure behavior law between the single coal seam mining and the coal seam mining under the close mined-out area was compared and analyzed by using UDEC numerical simulation software. The analysis results show that: compared with the single coal seam mining, the support pressure stress concentration of coal mining under the close-distance goaf is higher, the strength of advanced abutment pressure is greater, and the roof strata damage of the lower coal seams is more serious than that of single coal seam mining due to coal mining under close-distance goaf belongs to repeated mining. The support strength design of working face must consider the influence of the upper goaf. Thus, when mining under close-distance goaf, the measures that strengthen the advanced support of the underlying coal seam and improve the support strength of the hydraulic support in working face must be taken to ensure the effective management of the roof and safe mining. -
-
[1] 宋振骐,李绍泉,李伟.盘江矿区近距离多煤层下保护层开采可行性分析及技术实践[J].湖南科技大学学报(自然科学版),2011,26(1):5-8. SONG Zhenqi, LI Shaoquan, LI Wei. Feasibility analysis and engineering practice of low exploitation of protective seam of coal seam group with near distance in Panjiang mining areas[J]. Journal of Hunan University of Science & Technology(Natural Science Edition), 2011, 26(1): 5-8.
[2] 张向阳,常聚才.上下采空极近距离煤层开采围岩应力及破坏特征研究[J].采矿与安全工程学报,2014, 31(4):506-511. ZHANG Xiangyang, CHANG Jucai. Stress and failure characteristics of surrounding rock in the extremely close distance coal seams group mining after the upper and lower coal seam mining[J]. Journal of Mining & Safety Engineering, 2014, 31(4): 506-511.
[3] 张勇,刘传安,张西斌,等.煤层群上行开采对上覆煤层运移的影响[J].煤炭学报,2011,36(12):1990. ZHANG Yong, LIU Chuan’an, ZHANG Xibin, et al. The influence of ascending mining on the movement character of overlying coal seam in coal seams group[J]. Journal of China Coal society, 2011, 36(12): 1990.
[4] 黄庆享,李康华,曹健.浅埋近距离采空区下工作面矿压特征与顶板结构分析[J].陕西煤炭,2021,40(1):12-17. HUANG Qingheng, LI Kanghua, CAO Jian. Analysis on mine pressure characteristics and roof structure of working face under shallow buried and close goaf[J]. Shaanxi Coal, 2021, 40(1): 12-17.
[5] 汪北方,刘春保,梁冰,等.极近距离厚煤层房式采空区下综放开采覆岩破断失稳规律研究[J].采矿与安全工程学报,2020,37(6):1180-1187. WANG Beifang, LIU Chunbao, LIANG Bing, et al. Roof fracture and instability law of overlying strata in fully mechanized caving mining in ultra-close thick coal seams under the room mining goaf[J]. Journal of Mining & Safety Engineering, 2020, 37(6): 1180-1187.
[6] 许猛堂,徐佑林,金志远.房式采空区下近距离煤层开采支架工作阻力研究[J].煤炭科学技术,2020,48(8):63-69. XU Mengtang, XU Youlin, JIN Zhiyuan. Research on support resistance of contiguous coal seam mining under room-and-pillar gob[J]. Coal Science and Technology, 2020, 48(8): 63-69.
[7] 杨路林,李亚春,吴士良.近距离煤层采空区下综采面合理支架工作阻力确定研究[J].煤炭科学技术,2020,48(9):189-194. YANG Lulin, LI Yachun, WU Shiliang. Study on reasonable fully-mechanized mining support working resistance under gob of contiguous coal seam[J]. Coal Science and Technology, 2020, 48(9): 189-194.
[8] 杨路林.大采高长悬顶综放工作面压架机制及防治技术[J].煤炭技术,2017,36(8):257-260. YANG Lulin. Mechanism of support crushing and prevention technology of fully mechanized caving face with long hanging roof[J]. Coal technology, 2017, 36(8): 257-260.
[9] 尹时雨.上覆旺采采空区对下部近距离煤层开采矿压分布规律的影响与对策分析[J].煤矿安全,2019,50(8):137-140. YIN Shiyu. Influence of overlying wongawilli mining goaf on rock pressure distribution law of lower short distance coal seam and its countermeasures[J]. Safety in Coal Mines, 2019, 50(8): 137-140.
[10] 孙卓越,孟宪志,郝登云,等.带压开采工作面长度对底板破坏深度的影响[J].矿业研究与开发,2020,40(7):22-27. SUN Zhuoyue, MENG Xianzhi, HAO Dengyun, et al. Study on influence of the legth of working face on failure depth of floor in mining above aquifer[J]. Mining Research and Development, 2020, 40(7): 22.
[11] 樊勇.近距离煤层采空区下动压回采巷道合理布置研究[J].煤炭技术,2020,39(4):6-9. FAN Yong. Study on reasonable layout of mining roadway under dynamic pressure in goaf of close coal seam[J]. Coal Technology, 2020, 39(4): 6-9.
[12] 王震,娄芳,金士魁,等.极近距离煤层采空区下回采巷道位置及围岩控制研究[J].煤炭工程,2020,52(2):1-4. WANG Zhen, LOU Fang, JIN Shikui, et al. Roadway position and surrounding rock control technology under mining goaf in extremely close coal seam[J]. Coal Engineering, 2020, 52(2): 1-4.
[13] 梁勇,薛彦平,胡胜勇.近距离煤层群重复采动覆岩破坏规律分析研究[J].矿业研究与开发,2021,41(4):72-75. LIANG Yong, XUE Yanping, HU Shengyong. Study on overburden failure law of close distance coal seam group under repeated mining[J]. Mining Research and Development, 2021, 41(4): 72-75.
[14] 孙亚楠,张培森,颜伟,等.伴生台阶断层近距离煤层开采覆岩运移及应力变化规律试验研究[J].煤矿安全,2020,51(7):48-54. SUN Yanan, ZHANG Peisen, YAN Wei, et al. Experimental study on overburden movement and stress variation of coal seam mining with associated step faults[J]. Safety in Coal Mines, 2020, 51(7): 48-54.
[15] 王永东.极近距离煤层群上部煤层回采底板损伤深度分析[J].中国矿山工程,2020,49(3):38-42. WANG Yongdong. Analysis of the damage depth of the mining floor in the upper coal seam of the very close seam group[J]. China Mine Engineering, 2020, 49(3): 38-42.
[16] 赵兴华.近距离煤层上覆采空区下大断面切眼掘进技术研究[J].煤炭技术,2018,37(12):77-80. ZHAO Xinghua. Study on excavation technology of large section open-off cut under overlying mining goaf in close distance seams[J]. Coal Technology, 2018, 37(12): 77-80.
[17] 张风达,申宝宏,康永华.煤层底板破坏机理分析及最大破坏深度计算[J].矿业安全与环保,2015,42(3):58-61. ZHANG Fengda, SHEN Baohong, KANG Yonghua. Failure mechanism of coal seam floor and calculation of maximum breaks depth[J]. Mining Safety & Environment Protection, 2015, 42(3): 58-61.
[18] 张风达,高召宁,孟祥瑞.采场底板塑性区分布及破坏机理研究[J].长江科学院院报,2012,29(11):59. ZHANG Fengda. GAO Zhaoning, MENG Xiangrui. Failure mechanism and plastic zone distribution of coal mining floor[J]. Journal of Yangtze River Scientific Research Institute,2012, 29(11): 59.
-
期刊类型引用(19)
1. 王恩超,陈明振,高久国. 新形势下山东省煤矿顶板事故分析及防范探讨. 山东煤炭科技. 2024(03): 174-177+182 . 
百度学术
2. 王铁军. 五虎山煤矿顶空开采工作面矿压显现规律模拟研究. 煤. 2024(09): 62-66 . 百度学术
3. 李士栋,夏方迁,袁腾飞,吴震,曹洪义. 基于深部煤体应力监测的采动应力集中区域范围分析研究. 中国矿业. 2024(09): 147-157 . 百度学术
4. 刘建宇,张立辉,卞涛. 特厚煤层超大采高综采工作面冒顶防治技术. 中国矿业. 2024(S2): 265-269 . 百度学术
5. 黄自炎,张伟胜. 近距离煤层开采围岩破坏及支护阻力研究. 煤炭技术. 2023(02): 44-46 . 百度学术
6. 贾海宾,万晓,屈振祖,尚文政,袁健博. 上覆近距离遗留煤柱影响下采掘工作面应力场分析. 煤. 2023(07): 88-93+105 . 百度学术
7. 卞涛,刘建宇,张顺. 近距离煤层开采过上覆采空区影响分析. 中国矿业. 2023(S1): 309-312+322 . 百度学术
8. 庄通,田军,赵启峰,姜士源,杨学红,沈春阳. 近距离煤层下伏工作面巷道布置及顶板控制模拟分析. 华北科技学院学报. 2023(06): 44-54 . 百度学术
9. 徐大连. 张双楼煤矿坚硬顶板高效致裂技术体系研究. 内蒙古煤炭经济. 2023(24): 16-18 . 百度学术
10. 赵宇德. 近距离煤层开采合理巷道布置方法研究. 煤. 2022(02): 26-29 . 百度学术
11. 董俊亮. 保德煤矿高应力综放面回采巷道超前矿压显现特征研究. 煤炭与化工. 2022(03): 15-19 . 百度学术
12. 杨深,郭世达,翟俊杰,刘莉. 基于覆岩结构的近距离煤层顶板导高发育规律探究. 内蒙古煤炭经济. 2022(04): 4-6 . 百度学术
13. 白邦旭. 近距离煤层回采巷道支护方法研究. 山西焦煤科技. 2022(05): 14-18 . 百度学术
14. 戴文琦. 相邻综采工作面采空区覆岩压力分布特征研究. 煤矿安全. 2022(07): 195-200 . 本站查看
15. 刘文静,岳东,霍小泉,范智海,王新堂,赵玉桃,杨琛,贺斌雷,李刚,蒋上荣. 基于微震监测的近距离煤层重复采动覆岩裂隙发育特征研究. 煤炭技术. 2022(09): 23-28 . 百度学术
16. 李勇,王卓颖. 综放工作面矿压突变机理及应对措施. 煤矿安全. 2022(12): 226-234 . 本站查看
17. 孙梦迪,刘增辉,王帅帅,黄凯. 近距离采空区下大断面巷道顶板稳定分析. 科学技术与工程. 2022(36): 16001-16006 . 百度学术
18. 韩煜,韩伟,李金刚. 补连塔煤矿浅埋深极近距离下层煤开采穿越采空区模拟研究. 煤炭科学技术. 2022(S2): 61-68 . 百度学术
19. 张智,李金刚. 浅埋煤层超长工作面矿压规律研究. 煤炭科学技术. 2021(S2): 30-33 . 百度学术
其他类型引用(7)
计量
- 文章访问数: 42
- HTML全文浏览量: 0
- PDF下载量: 18
- 被引次数: 26
下载:
