| 摘要: |
| 煤层倾角是影响底板破坏带深度的一个重要因素,为深入研究煤层倾角对底板破坏带深度的影响,采用断裂力学理论建立了煤层倾角对底板破坏带深度影响的计算模型,得出由于煤层倾角的存在,倾斜工作面上部破坏带深度小于下部破坏带深度。收集我国大量的突水案例与煤层倾角统计数据,以及破坏带深度与煤层倾角统计数据,从突水案例数据可以看出倾斜工作面下部由于底板破坏造成的突水次数明显多于上部,从破坏带深度与煤层倾角变化趋势可以看出随着倾角增大破坏带深度也在增大。统计得到数据的结论与应用断裂力学模型分析得到的结论一致。最后对建立的破坏带深度计算模型井下质量检验,检验结果显示该计算模型的精度较高,符合现场应用的要求。 |
| 关键词: 底板破坏带 破坏带深度 煤层倾角 工作面斜长 断裂力学 |
| DOI:10.7515/JEE182026 |
| CSTR:32259.14.JEE182026 |
| 分类号: |
| 基金项目:国家自然科学基金项目(51174109,51074086) |
| 英文基金项目:National Natural Science Foundation of China (51174109, 51074086) |
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| Formula derivation of calculating depth of failing zone in floor of inclined working face |
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SHEN Hao, WU Weining, ZHANG Bo
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Graduate School of Liaoning Technical University, Fuxin 123000, China
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| Abstract: |
| Background, aim, and scope In recent years, mining technology and technology level has been rapid development, the number of long working face and deep mining face is increasing, and the problem of water damage of floor in our country is increasing. This problem has been paid more and more attention by many experts and scholars in the industry. The Wu Qiang academician applied the vulnerability index method and GIS system to study the causes and prediction of the floor water damage, and put forward the “three graph double prediction” method, which has received great attention in the industry and site application effect has also been unanimously praised. Professor Jiang Zhenquan and Professor Wang Lianguo have also made some achievements in the research on the developmental characteristics and distribution of the failure zone in the floor, and put forward the method of judging the water inrush from the floor. Professor Shi Longqing and his team have made an in-depth study on the influencing factors of the depth of the failure of the floor, and established the prediction model of the depth of the failure zone of the floor according to the influence degree of each factor. This paper mainly studies the influence of coal seam dip angle on the depth of failure zone in floor. Materials and methods The stress distribution characteristics of the posterior floor of the inclined working face are analyzed by using the fracture mechanics, and the failure zone calculation model of the lower edge and the upper edge of the inclined working face is established based on the fracture mechanics model. Results From the above calculation model of the failure zone, the damage zone of the upper and lower edges is the same when the dip angle of the coal seam is 0°, and the depth of the failure zone of the lower edge is larger than that of the upper edge when the dip angle of the coal seam is not 0°. The depth of the failure zone at the upper edge of the working face decreases with the increase of the inclination angle of the working face, and the depth of the failure zone of the lower edge increases with the increase of the inclination angle. Discussion From the case of water bursting in China’s coal mine and the depth of the inclination working face can be seen: the location of the water burst occurs mostly at the lower edge of the inclination working face, and the depth of the failure zone of the bottom plate is increasing with the increase of the inclination angle of the coal seam. Conclusions The results of theoretical analysis and statistical data can be concluded that the dip angle of the coal seam has a significant effect on the depth of the failure zone of the floor. With the increase of the dip angle of the coal seam, the depth of the lower edge of the inclined working face becomes larger and the depth of the upper edge is smaller. Recommendations and perspectives The established failure zone depth calculation model was subjected to quality inspection. The model is used to calculate the depth of the failure zone under actual conditions, and compared with the observed failure zone depth. The average error between the calculated result and the measured result is 1.20 m, which indicates that the model has high accuracy and meets the requirements in engineering application. |
| Key words: failing zone of floor depth of failing zone dip angle of coal seam inclined length of working face compressive strength |
