刘学生, 李学斌, 谭云亮, 范德源, 倪萍, 解成成, 宋虎. 深部沿空巷道巷旁支护失稳机制与降能控制方法[J]. 煤炭学报, 2023, 48(S2): 485-500. DOI: 10.13225/j.cnki.jccs.2022.1422
引用本文: 刘学生, 李学斌, 谭云亮, 范德源, 倪萍, 解成成, 宋虎. 深部沿空巷道巷旁支护失稳机制与降能控制方法[J]. 煤炭学报, 2023, 48(S2): 485-500. DOI: 10.13225/j.cnki.jccs.2022.1422
LIU Xuesheng, LI Xuebin, TAN Yunliang, FAN Deyuan, NI Ping, XIE Chengcheng, SONG Hu. Instability mechanism and control method of energy-reducing for roadside support in deep gob-side roadway[J]. Journal of China Coal Society, 2023, 48(S2): 485-500. DOI: 10.13225/j.cnki.jccs.2022.1422
Citation: LIU Xuesheng, LI Xuebin, TAN Yunliang, FAN Deyuan, NI Ping, XIE Chengcheng, SONG Hu. Instability mechanism and control method of energy-reducing for roadside support in deep gob-side roadway[J]. Journal of China Coal Society, 2023, 48(S2): 485-500. DOI: 10.13225/j.cnki.jccs.2022.1422

深部沿空巷道巷旁支护失稳机制与降能控制方法

Instability mechanism and control method of energy-reducing for roadside support in deep gob-side roadway

  • 摘要: 侧向基本顶断裂下沉引起的巷旁支护体能量积聚及其突发释放是导致深部沿空巷道围岩失稳破坏的根源之一。以山东泰安孙村煤矿千米埋深工作面开采为工程背景,利用UDEC离散元数值模拟软件获得了实际工程条件下沿空巷道围岩能量演化规律,以及巷旁支护体宽度、侧向基本顶厚度和断裂长度等因素对沿空巷道围岩能量演化规律影响特征。在此基础上,基于顶板横向断裂边缘的弧形三角板结构,建立了沿空巷道侧向顶板结构力学模型,分析了不同采动阶段巷旁支护体的力学状态,揭示了侧向基本顶断裂下沉引起支护体动力失稳机理,获得了支护体发生动力失稳的能量判据N,并以此为指标提出了"降低外部冲击能量+改变内部承载性能"的巷旁支护体稳定性降能控制方法。当N ≥ 1时,支护体内积聚的弹性变形能与侧向基本顶断裂所带来的新增变形能之和大于支护体完全破碎需要消耗的能量,支护体内部弹性能积聚较大,自承载能力发挥不足,支护体将发生动力失稳;反之,当N<1时,支护体不会发生动力失稳现象。现场实践表明,所建立的动力失稳能量判据与实际结果相吻合,采用降能控制方法后,沿空巷道顶底板移近量、两帮移近量最大值分别114和123 mm,锚索受力相对值最终稳定为50 kN左右,巷旁充填体冲击破坏现象基本消除,稳定性明显提高,控制效果显著。

     

    Abstract: The energy accumulation and sudden release of the roadside support body caused by the fracture and subsidence of the lateral main roof are one of the causes of instability and failure of surrounding rock in the deep gob-side roadway. Taking the working face with a depth of 1 000 m in the Suncun Coal Mine, Taian, shandong Province as the engineering background, the energy evolution law of the surrounding rock of the gob-side roadway under the actual engineering conditions was obtained by the UDEC discrete element numerical simulation software. Also, the influence characteristics of factors such as the width of the roadside support body, the thickness of the lateral main roof and the fracture length on the energy evolution law of gob-side roadway were obtained. Therefore, based on the arc triangular plate structure of the transverse fracture edge of the roof, the mechanical model of the lateral roof structure of the gob-side roadway was constructed, and the mechanical state of the roadside support body in different mining stages was analyzed. The dynamic instability mechanism of the roadside support body caused by the fracture and subsidence of the lateral main roof was revealed, and the energy criterion of dynamic instability N of the support body was obtained. Based on this index, the control method of energy-reduction of the stability for roadside support body was proposed, which was "reducing external impact energy + changing internal bearing capacity". When N ≥ 1, the sum of the storage energy of the elastic zone and the new increased deformation energy brought by the fracture of the lateral main roof is greater than the energy consumed by the complete crushing of the plastic zone of the roadside support body. At this time, the elastic energy accumulated in the support body is large, the self-bearing capacity of the support body is insufficient, and the support body will undergo dynamic instability, and when N<1, the support body will not occur dynamic instability. Field practice shows that the energy criterion of dynamic instability established is consistent with the actual results. After adopting the control method of energy-reduction, the maximum values of the displacement of the roof and floor and two sides were 114 and 123 mm, respectively, and the relative force of anchor cable was finally stabilized at about 50 kN. The impact failure phenomenon of the support body was basically eliminated, the stability was obviously improved, and the control effect was remarkable.

     

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