Study on roof breaking mechanism and support stability of steeply dipping seam and large mining height

IF 1.9 4区 工程技术 Q4 ENERGY & FUELS Energy Exploration & Exploitation Pub Date : 2023-09-28 DOI:10.1177/01445987231203464
Bosheng Hu, Panshi Xie, Baofa Huang, Yongping Wu, Jianjie Chen
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Abstract

Taking the steeply dipping and large mining height working face of a mine as the engineering background, through the combination of physical simulation experiment, numerical calculation, theoretical analysis and field monitoring, based on a comprehensive analysis of the deformation and failure characteristics of the macrostructure of surrounding rock, the roof breaking mechanism and support instability characteristics of large mining height working face under the angle effect are studied. The research shows that due to the influence of the dip angle of the coal seam, the roof stress is asymmetrically deflected along the tendency, and the load of the overlying strata is transmitted to the upper and lower coal bodies with the stress-deflection boundary as the boundary, resulting in the deformation and failure of the roof and the filling showing obvious asymmetric characteristics. With the increase of dip angle, the asymmetric characteristics of roof stress transfer are enhanced, the stress release arch is reduced, the height of caving zone is reduced, the deformation and failure area is gradually moved up, and the regional characteristics of roof loading and deformation and failure are more obvious, which leads to the significant increase of unbalanced loading degree and instability probability of supports in different areas. Combined with the actual production, the prevention and control measures of hard roof caving and support crushing in fully mechanized mining face with steeply dipping seam and large mining height are put forward.
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大采高急倾斜煤层破顶机理及支护稳定性研究
以某矿山急倾斜大采高工作面为工程背景,通过物理模拟实验、数值计算、理论分析和现场监测相结合,在综合分析围岩宏观结构变形破坏特征的基础上,研究了倾角作用下大采高工作面顶板破断机理和支护失稳特征。研究表明,受煤层倾角的影响,顶板应力沿倾向性发生不对称偏转,上覆岩层的荷载以应力-偏转边界为边界传递给上下矿体,导致顶板变形破坏和充填呈现明显的不对称特征。随着倾角的增大,顶板应力传递的不对称特征增强,应力释放拱减小,垮落带高度减小,变形破坏区域逐渐上移,顶板加载和变形破坏区域特征更加明显,导致不同区域支架不平衡加载程度和失稳概率显著增加。结合生产实际,提出了大倾角煤层大采高综采工作面硬顶板冒落和支架破碎的防治措施。
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来源期刊
Energy Exploration & Exploitation
Energy Exploration & Exploitation 工程技术-能源与燃料
CiteScore
5.40
自引率
3.70%
发文量
78
审稿时长
3.9 months
期刊介绍: Energy Exploration & Exploitation is a peer-reviewed, open access journal that provides up-to-date, informative reviews and original articles on important issues in the exploration, exploitation, use and economics of the world’s energy resources.
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