|
|
|
| Breaking mechanism and control countermeasures of anchor bolt in roadway retaining filling body |
| Yang Hongzeng 1,2,3,4 |
| 1. National Energy Key Laboratory of Backfilling Mining Technology, Xingtai 054000, China; 2. Hebei Coal Research Institute Co. Ltd., Xingtai 054000, China; 3. Hebei Backfilling Mining Technology Co., Ltd., Xingtai 054000, China; 4. Hebei Innovation Center of Backfilling Coal Mining Technology, Xingtai 054000, China |
|
|
|
|
Abstract Aiming at the breaking problem of anchor bolt in roadway retaining filling body, No. C0202 Face of Chiyu Mine was taken as the engineering background, the breaking characteristics and mechanism of anchor bolt were analyzed by field investigation, laboratory test, mechanical modeling and theoretical analysis. The research showed that the bolt fracture mainly concentrates on the thread section, which was mainly brittle fracture. The failure process was divided into three stages: crack propagation, rapid propagation and instantaneous fracture. The concentrated load on the tail thread section was 5 ~ 7 times the load on the rod body, which was the main reason for the breakage. The strength factor K of fracture mechanics was introduced to establish the mechanical model. The analysis showed that the critical size depth was jointly affected by the pretightening force and the construction angle of the bolt, which were proportional and inversely proportional. The larger the pre-tightening force, the smaller the installation angle, the larger the critical fracture size, the less easily the rod was broken. Based on the above research, the breaking reasons were analyzed in detail from the aspects of dynamic pressure influence and anchor bolt material, and the corresponding improvement measures were put forward to effectively avoid the breaking of anchor bolt and ensure the success of roadway retaining.
|
|
|
|
|
|
| [ 1 ] 华心祝,李 琛,刘 啸,等. 再论我国沿空留巷技术发展现状及改进建议[ J ]. 煤炭科学技术,2023,51( 1 ):128 - 145.
[ 2 ] 闫殿华. 柔模混凝土墙沿空留巷循环交替支护成套装备应用[ J ]. 煤矿机械,2023,44( 12 ):145 - 147.
[ 3 ] 胡明明,周 辉,张勇慧,等. 宽断面预留墩柱沿空留巷墩柱支护阻力计算研究[ J ]. 岩土力学,2018,39( 11 ):4 218 - 4 225.
[ 4 ] 孙春东. 超高水材料充填采煤技术[ M ]. 北京:科学出版社,2017.
[ 5 ] 郝胜鹏. 沿空留巷巷旁充填体稳定机理研究[ D ]. 徐州:中国矿业大学,2017.
[ 6 ] 韩俊效,马晋民,石晋松,等. 大宁煤矿阶段式高水材料充填沿空留巷技术应用研究[ J ]. 煤炭工程,2020,52( 4 ):6 - 11.
[ 7 ] 李夕兵,马少维,马春德,等. 锚杆尾部断裂机制和防破断方法应用[ J ]. 科技导报,2013,31( 8 ):27 - 31.
[ 8 ] 张国杰,王卫军. 深部高应力巷道锚杆脆塑性破断机理研究[ J ]. 中州煤炭,2016( 8 ):79 - 84.
[ 9 ] 王 傲,姚强岭,李学华,等. 采动高应力区沿空掘巷锚杆破断机理[ J ]. 中国矿业大学学报,2017,46( 4 ):769 - 775.
[ 10 ] 刘金海,孙 浩,张治高,等. 高预紧力锚杆破断及其控制的宏观力学机制研究[ J ]. 煤炭科学技术,2019,47( 1 ):91 - 96.
[ 11 ] 樊克恭,王亚军,甄恩泽,等. 深部沿空掘巷肩角锚杆破断机理分析[ J ]. 辽宁工程技术大学学报(自然科学版),2015,34( 10 ):1 120 - 1 124.
[ 12 ] 高东忍. 深埋大断面煤巷锚杆破断机理与控制技术研究[ D ]. 徐州:中国矿业大学,2016.
[ 13 ] 孙春东,刘树轮,李继升. 超高水材料在煤矿的系列应用技术[ J ]. 煤炭科学技术,2017,45( 8 ):42 - 47.
[ 14 ] 游小伟. 赤峪矿高水材料沿空留巷技术研究[ D ]. 邯郸:河北工程大学,2015.
[ 15 ] GB/T 39336-2020. 沿空留巷高水材料巷旁袋式充填技术要求[ S ].
[ 16 ] 卓卫东. 应用弹塑性力学[ M ]. 北京:科学出版社,2021.
[ 17 ] 文龙飞,王理想,田 荣. 动载下裂纹应力强度因子计算的改进型扩展有限元法[ J ]. 力学学报,2018,50( 3 ):599 - 610.
[ 18 ] 吴拥政,康红普. 强力锚杆杆体尾部破断机理研究[ J ]. 煤炭学报,2013,38( 9 ):1 537 - 1 541.
[ 19 ] 程 蓬,鞠文君. 高强度锚杆尾部螺纹断裂受力分析[ J ]. 煤矿开采,2011,16( 2 ):20 - 22,90.
[ 20 ] 康红普,王金华. 煤巷锚杆支护理论与成套技术[ M ]. 北京:煤炭工业出版社,2007. |
|
|
|
