Classification and instability mechanism of anchored “beam-arch” composite structure in rock burst roadways with top-coal

被引：0

作者：

Cao A. ^{[1
,3
]}

Guo W. ^{[1
,2
]}

Wen Y. ^{[1
,2
]}

Wang S. ^{[1
]}

Liu Y. ^{[1
]}

Hao Q. ^{[1
]}

Lü G. ^{[1
]}

Li G. ^{[1
]}

机构：

[1] School of Mines, China University of Mining & Technology, Xuzhou

[2] School of Geology and Mining Engineering, Xinjiang University, Urumqi

[3] Jiangsu Engineering Laboratory of Mine Earthquake Monitoring and Prevention, China University of Mining & Technology, Xuzhou

来源：

Meitan Xuebao/Journal of the China Coal Society | 2024年 / 49卷 / 04期

关键词：

amplification effect of load stres; elastic wave; support optimization; thickness of top-caol; beam-arch” composite structure;

D O I：

10.13225/j.cnki.jccs.2023.1636

中图分类号：

学科分类号：

摘要：

The rock burst frequently occurs in the roadways with top coal, and the roof disasters are particularly severe under dynamic stress in China. In order to explore the classification and instability mechanisms of anchoring structures in the roadways with top-coal, analog simulation experiments, theoretical analysis, and data statistics were used under the engineering background of the large-area rock burst roof failure in the Working Face 301 of a mine in Shaanxi Province, China. The dynamic load response characteristics of the stress, displacement, and surface acceleration of the surrounding rock in the roadways with top coal were analyzed. The classification characteristics of the roof anchoring structure under the influence of top coal thickness and cables were studied. The stress response mechanism of the roadways with top coal under elastic waves was explored, and the instability mechanism of the anchoring “beam arch” structure was proposed. The rock burst resistance of the air-return roadway in the Working Face 301 was evaluated, and the corresponding optimization schemes for the “beam-arch” composite structure were proposed. The results show that ① the monitoring data of stress and displacement of the surrounding rock in the roadways with top coal under dynamic stress verify the existence of internal and external beam or arch anchoring structures in the roof. Due to the increase in the thickness of top coal, there is a transition from “beam” to “arch” in the anchoring structure of the inner layer of the roof; ② based on the relative relationship between the thickness of the top coal and the cables, the roof anchoring structure is divided into “superimposed-beam and arch” for thin top coal, “composite-beam and arch” for thick top coal, and “combined arch” for extra thick top coal. A critical thickness index for the transformation of thick coal beams from “beam” to “arch” is established; ③ the instability mechanism of the beam structure and the arch structure is that they fail after reaching their tensile and shear strength limits under dynamic and static stress, respectively. The amplification effect of the “beam-arch” composite structure on the load stress is significantly affected by its size; ④ the bearing strength of the inner arch in the "combined arch" structure is relatively low. Increasing the length of cables can increase the thickness of the inner arch, and the corresponding “combined arch” structure’s bearing strength increases significantly, which is consistent with the evaluation results of the rock burst resistance. © 2024 China Coal Society. All rights reserved.

引用

页码：1752 / 1770

页数：18

共 32 条

[1] WANG Lianhe, CAO Anye, GUO Wenhao, Et al., Rockburst mechanics and characteristics of roadways in “fault-fold” structure area[J], Journal of Mining & Safety Engineering, 40, 1, (2023)
[2] LIU Jinhai, SUN Hao, TIAN Zhaojun, Et al., Effect of advance speed on rock burst in coal mines and its dynamiccontrol method[J], Journal of China Coal Society, 43, 7, (2018)
[3] JING Hongwen, WU Jiangyu, YIN Qian, Et al., Particle flow simulation of rock burst and roof fall of deep coal roadway under dynamic disturbance[J], Chinese Journal of Rock Mechanics and Engineering, 39, S2, pp. 3475-3487, (2020)
[4] WU Yongzheng, FU Yukai, HE Jie, Et al., Principle and technology of “pressure relief-support-protection” collaborative prevention and control in deep rock burst roadway[J], Journal of China Coal Society, 46, 1, pp. 132-144, (2021)
[5] CAI M., Principles of rock support in burst-prone ground[J], Tunnel-ling and Underground Space Technology, 36, (2013)
[6] LIU Xiaohui, XUE Yang, ZHENG Yu, Et al., Research on energy release in coal rock fragmentation process under impact load[J], Chinese Journal of Rock Mechanics and Engineering, 40, S2, pp. 3201-3211, (2021)
[7] WANG Meng, SONG Zifeng, ZHENG Dongjie, Et al., Development and application of rock energy dissipation model in FLAC<sup>3D</sup>[J], Journal of China Coal Society, 46, 8, pp. 2565-2573, (2021)
[8] KONG Linghai, Impact failure law of deep coal roadway under incremental loadbased on similar simulation test[J], Journal of China Coal Society, 46, 6, pp. 1847-1854, (2021)
[9] SHI Tianwei, PAN Yishan, WANG Aiwen, Et al., Classification of rock burst in coal mine based on energy storage and release bodies[J], Journal of China Coal Society, 45, 2, pp. 524-532, (2020)
[10] PAN Junfeng, LIU Shaohong, XIA Yongxue, Et al., Impact failure characteristics and support methods of roadway in largely-inclined broken coal seams[J], Journal of Mining& Safety Engineering, 38, 5, pp. 946-953, (2021)

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