Analysis of failure mode and deformation evolution characteristics of slopes under the influence of highwall mining

被引:0
|
作者
Wang W. [1 ]
Li J. [1 ]
Wang C. [1 ]
Chen S. [1 ]
Wang P. [1 ]
机构
[1] Institute of Mining, Inner Mongolia University of Science and Technology, Baotou
来源
Meitan Kexue Jishu/Coal Science and Technology (Peking) | 2023年 / 51卷 / 07期
关键词
anti-dip instability; collapse instability; material proportion; slope instability; slope stability; subsidence faded area;
D O I
10.13199/j.cnki.cst.2022-0593
中图分类号
学科分类号
摘要
The slope has the typical deformation failure and instability characteristics under the interaction of natural and human factors which has been given a lot of attention in geotechnical and mining engineering. During highwall mining, in particular, deformation evolution characteristics and failure mode are more complex under dual influence of open pit mine and underground mine. Physical modelling is an important means to study the characteristics and behavior of deformation and evolution of various types of rock and soil mass, and it is also an important supplement to the field study of large-scale rock and soil mass. It is widely used in mines and geotechnical engineering. The determination of the material used for physical modeling is the foundation and key links of research. Therefore, the article firstly selected river sand/aggregate, lime and gypsum/cemented material as the experimental materials through the relevant literature review and based on the principle of economic and convenience, and adopted two proportioning schemes to make standard specimens. The uniaxial compression test was carried out to compare and analyze the strength of the original rock, and it was determined that the scheme 2 could be used as the research scaling number of the physical modelling; Secondly, on the basis of determining the material proportion, the physical and structural model of highwall mining is established, and the analysis shows that the evolution characteristics of slope deformation and failure in the process of highwall mining can be divided into superficial transformation stage, structural transformation stage and aging deformation stage, the deformed and damaged rock mass can be divided into “vertical three zones”, namely caved zone, fractured zone and continuous bending zone. According to the length of the panel, the coal seam can be divided into three stages: initial stage, middle stage and final stage. The lower coal seam can be divided into two stages: the initial stage and the final stage. The evolution of the slope rock mass due to the extraction of the upper coal seam to the stopping line is characterized by the formation of subsidence faded areas along the center of the goaf to both sides, and finally a symmetrical distribution of semi-“pyramid” shape is formed. The rock mass that is deformed and damaged due to the extraction of the lower seam to the mining stop line is in a semi-curve-like shape; Finally, based on the analysis of physical modelling and field monitoring, it is concluded that when the upper coal seam of the highwall coal seam is mined to about 120 m, the slope shows a slight instability. When the lower coal seam is mined to about 120 m, the goaf between the upper and lower coal seams is connected, and the instability is intensified until the mining reaches the stopping line. In the upper part of the slope, 1 400 step forms a local collapse instability zone pointing to the open-pit, while the rest of the step are anti-dip instability pointing to the goaf. © 2023 China Coal Society. All Rights Reserved.
引用
收藏
页码:321 / 336
页数:15
相关论文
共 40 条
  • [31] XU Qiang, LIU Hanxiang, ZOU Wei, Et al., Large scale shaking table test study of acceleration dynamic response characteristics of slopes[J], Chinese Journal of Rock Mechanics and Engineering, 29, 12, (2010)
  • [32] WANG Chuangye, LI Junpeng, LIU Wei, Et al., Study on the timeliness of slope stability under open well combined mining[J], Safety in Coal Mines, 49, 8, (2018)
  • [33] ZHANG Qiangyong, LI Shucai, GUO Xiaohong, Research and development of new typed cementitious geotechnical similitude material for iron crystal sand and its application[J], Rock and Soil Mechanics, 39, 8, (2008)
  • [34] NING Yibing, TANG Huiming, ZHANG Bocheng, Et al., Study on ratio of similar materials in rock based on orthogonal design and application of physical model test of bottom friction[J], Rock and Soil Mechanics, 41, 6, (2020)
  • [35] WANG Chuangye, LI Junpeng, ZHANG Qi, Et al., Research on movement law of overburden rock on open-pit slope under underground mining conditions[J], Mining Research and Development, 38, 4, (2018)
  • [36] LI Shugang, WANG Linhua, LIN Haifei, Et al., Similar simulation experiment and analysis on evolution characteristics of "three zones"in overburden strata of stope[J], Mining Safety & Environmental Protection, 40, 3, (2013)
  • [37] WANG Zhiqiang, LI Pengfei, WANG Lei, Et al., Method of division and engineering use of“three band”in the stope again[J], Journal of China Coal Society, 38, S2, (2013)
  • [38] FAN Gangwei, ZHANG Dongsheng, MA Liqiang, Overburden movement and fracture distribution induced by longwall mining of the shallow coal seam in the Shendong coalfield[J], Journal of China University of Mining & Technology, 40, 2, (2011)
  • [39] ZUO Jianping, WU Genshui, SUN Yunjiang, Et al., Investigation on the inner and outer analogous hyperbola model(AHM) of strata movement[J], Journal of China Coal Society, 46, 2, (2021)
  • [40] MA Kang, Sensitivity analysis of factors affecting stability of steep rock slope and study on treatment Countermeasures, (2016)