首页|期刊导航|河南理工大学学报(自然科学版)|深埋采场直覆厚硬顶板破断动载效应及沿空巷道稳定机理

深埋采场直覆厚硬顶板破断动载效应及沿空巷道稳定机理OA

Dynamic fracturing effects of the immediately overlying thick,hard roof in deep mining and the stability mechanisms of gob-side roadways

中文摘要英文摘要

目的 针对兖州矿区深埋采场直覆厚硬顶板下沿空巷道冲击失稳问题,以济宁三号煤矿183下06工作面运输巷为工程背景,探究其灾变机理并提出控制技术.方法 采用现场调研、理论分析、数值模拟和现场试验结合的方法,建立采场直覆厚硬顶板悬臂梁力学模型,系统分析其采动承载状态和能量积聚演化分布规律,揭示顶板不同特性对沿空巷道灾变失稳的影响,阐明直覆厚硬顶板下沿空巷道动载型失稳定义、孕育发生过程,提出并应用基于变径封孔、顶板锚固-注浆耦合强化技术的成层式联合控制体系.结果 结果表明:(1)厚硬顶板采动能量积聚分布受其赋存特性影响显著:顶板强度越高、厚度越大,其弯曲能量峰值越低,能量集中性也越弱;反之,顶板悬露长度越长、上覆岩层荷载越大,则积聚的弯曲能量峰值越高,高应力区范围也越显著.(2)深部巷道动载型失稳本质为厚硬顶板破断强动载扰动作用下巷道围岩能量急剧释放和结构动态劣化过程,表现为煤体抛出、支护体系失效等动力现象.(3)提出变径封孔卸压和顶板锚固-注浆耦合强化技术结合的成层式联合控制策略,形成针对直覆厚硬顶板的成层式防护体系.结论 现场试验表明,该技术有效保障了直覆厚硬顶板下沿空巷道围岩稳定,对同类型巷道支护具有参考意义.

Objectives To address impact-induced instability of gob-side roadways beneath immediately over-lying thick,hard roof in deep mining faces of the Yanzhou mining area,the transport roadway of the 18306 working face in Jisan Coal Mine is taken as the engineering background to investigate the underlying disaster mechanisms and propose effective control technologies.Methods A comprehensive approach inte-grating field investigation,theoretical analysis,numerical simulation,and in-situ testing is employed.A cantilever-beam mechanical model of the immediately overlying thick,hard roof is established to systemati-cally analyze its mining-induced load-bearing behavior and the evolution characteristics of energy accumula-tion.The influences of roof properties on the catastrophic instability of gob-side roadways are revealed,and the definition and evolutionary process of dynamic instability under thick,hard roof conditions are clarified.On this basis,a layered collaborative control system integrating variable-diameter borehole sealing and coupled roof anchoring–grouting reinforcement is proposed and implemented.Results 1.The accumulation and distribution of mining-induced energy in thick,hard roof strata are significantly influenced by their in-herent geological and mechanical properties.Higher roof strength and greater thickness correspond to lower peak bending energy and weaker energy concentration,whereas longer roof suspension lengths and greater overlying loads result in higher peak bending energy accumulation and a more extensive high-stress zone.2.Dynamic instability of deep roadways essentially results from rapid energy release and structural degrada-tion of surrounding rock under strong dynamic disturbances induced by thick,hard roof fracturing,typi-cally manifested as coal ejection and support system failure.3.A layered collaborative control strategy com-bining pressure relief through variable-diameter borehole sealing and roof anchoring–grouting reinforce-ment is developed,forming a targeted protection system for immediately overlying thick,hard roofs.Con-clusions Field tests demonstrate that the proposed technology effectively ensures the stability of surround-ing rock in gob-side roadways beneath immediately overlying thick,hard roofs,providing a valuable refer-ence for support design in similar roadway conditions.

张广超;刘宇航;尹茂胜;张照允;郑灿广;张荣刚;雷腾;赵西坡

山东科技大学 能源与矿业工程学院,山东 青岛 266590山东科技大学 能源与矿业工程学院,山东 青岛 266590山东科技大学 能源与矿业工程学院,山东 青岛 266590兖矿能源集团股份有限公司,山东 济宁 272000兖矿能源集团股份有限公司,山东 济宁 272000山东科技大学 能源与矿业工程学院,山东 青岛 266590山东科技大学 能源与矿业工程学院,山东 青岛 266590兖矿能源集团股份有限公司,山东 济宁 272000

矿业与冶金

动载型失稳直覆厚硬顶板沿空巷道动力灾害成层式联合控制

dynamic instabilityimmediately overlying thick,hard roofgob-side roadwaydynamic disas-terlayered collaborative support

《河南理工大学学报(自然科学版)》 2026 (2)

86-96,11

国家自然科学基金资助项目(52374098)山东省自然科学基金资助项目(ZR202211070181)山东省"泰山学者"青年计划项目(tsqn202408186)

10.16186/j.cnki.1673-9787.2025080022

评论