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Gold Science and Technology ›› 2022, Vol. 30 ›› Issue (5): 733-742.doi: 10.11872/j.issn.1005-2518.2022.05.031

• Mining Technology and Mine Management • Previous Articles     Next Articles

Numerical Simulation Study on Shaft Construction Process of Water-rich Moraine Layer

Jiang GUO(),Niming JIANG,Xin CHENG   

  1. School of Resources and Safety Engineering,Central South University,Changsha 410083,Hunan,China
  • Received:2022-02-22 Revised:2022-06-15 Online:2022-10-31 Published:2022-12-10

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Abstract:

As an important part of mine construction,shaft engineering is also a key project to ensure the normal operation of the mine.With the continuous development and utilization of resources,the difficulty of resource extraction also increases,and more and more shaft projects need to be constructed under complex geological conditions.Moraine layer is a special geotechnical material widely distributed in the western region of China,there is more and more construction projects on this type of soil.Compared with the general sur-rounding rock structure,the soil mass of the moraine layer is basically composed of debris,the surrounding rock is mostly in a soft plastic state,the degree of consolidation is low,and the stability of the soil body is poor. The pressure is high,and the general shaft construction method is difficult to apply to the construction of this type of soil.Therefore,in order to improve the construction efficiency of the shaft under the geological conditions of the moraine layer,control the deformation of the surrounding rock during the construction of the shaft under the soil condition of the moraine layer,and optimize the construction plan of the shaft under the soil condition of the moraine layer.Taking the 8# shaft project of Xiaomaliu tailings pond in Sichuan as an example,using the research method of numerical analysis,combined with the actual engineering situation,considering the influence of underground diving in the moraine layer soil on the construction operation of the shaft,the shaft construction process of the vertical shafts by forward excavation method,full-section reverse shaft method and reverse shaft pilot tunnel expansion method were analyzed,and the distribution of pore water pressure,stress,displacement and plastic zone after the construction of the three types of shafts were analyzed.It can be seen from the simulation results that the construction effect of the excavation method is better,followed by the forward excavation method,and the construction effect of the full-section reverse method is the worst.The pore water pressure of the shaft seepage field and the surrounding rock stress on the side wall of the shaft in the construction of the raised shaft excavation method are relatively small,and the maximum deformation of the surrounding rock on the side wall of the shaft is only 4 cm.Similar,the maximum displacement reaches 7 cm.The full-section back-well method has poor construction effect,the groundwater can’t be discharged in time,the pore water pressure on the side wall of the shaft is large,and the deformation of the surrounding rock on the side wall of the shaft is large,reaching 10 cm.Therefore,among the three types of shaft construction schemes,the excavation method of the raised shaft can effectively control the soil deformation around the shaft.

Key words: shaft construction, moraine layer, fluid-solid analysis, stress distribution, displacement change, plastic zone

CLC Number: 

  • TU42

Fig.1

Geological conditions of the covered section of the shaft engineering"

Fig.2

Schematic diagram of groundwater control scheme"

Fig.3

Three-dimensional finite element numerical analysis model"

Fig.4

Surrounding rock samples(a) and test equipment(b)"

Table 1

Physical and mechanical parameters of soil layer"

土层类型层厚/m

密度

/(kg?m-3

泊松比

弹性模量

/MPa

黏聚力/kPa

内摩擦角

/(°)

孔隙率

渗透系数

/(m2?Pa-1?s-1

砾砂土层101 9100.327.962340.357.6×10-9
中、强风化玄武岩402 5000.280.00120450.304.0×10-7
冰碛层662 3500.1100.0015300.501.0×10-10

Fig.5

Distribution map of pore water pressure"

Fig.6

Stress distribution map of the shaft sidewall"

Fig.7

Variation law of vertical displacement of shaft sidewall rock"

Fig.8

Variation law of lateral displacement of shaft sidewall rock"

Fig.9

Distribution of surrounding rock plastic zone"

Table 2

Initial factor data of each construction scheme"

方案

类型

应力/MPa位移/m塑性区体积/m3
竖向侧向竖向侧向拉伸破坏区剪切破坏区
方案A1.911.150.0590.040157.471 149.53
方案B1.101.450.0410.088653.653 299.84
方案C2.231.130.0250.03810.89140.56

Table 3

Weight results of evaluation index"

评价指标指标变异性指标冲突性信息量权重/%
应力竖向0.5159.1854.73435.25
侧向0.5603.0011.68112.52
位移竖向0.5004.7542.37817.71
侧向0.5663.0261.71312.76
塑性区拉伸破坏区0.5242.8491.49311.12
剪切破坏区0.5112.7981.42910.64

Fig.10

Construction diagram of collapse section of shaft"

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