Study on the ultimate bearing capacity of surrounding soil underlying gripper of shaft boring machine

被引：0

作者：

Li C. ^{[1
]}

Li T. ^{[1
]}

Jing G.-Y. ^{[2
]}

Xiao Y.-H. ^{[1
]}

机构：

[1] Key Laboratory of Urban Underground Engineering of Ministry of Education, Beijing Jiaotong University, Beijing

[2] China Coal Research Institute, Mine Construction Branch, Beijing

来源：

Li, Tao (taoli@bjtu.edu.cn) | 1600年 / Academia Sinica卷 / 41期

关键词：

Failure mode; Gripper; Shaft boring machine; Soil; Ultimate bearing capacity;

D O I：

10.16285/j.rsm.2019.0879

中图分类号：

学科分类号：

摘要：

When shaft boring machine is tunnelling in strata, the inadequate bearing capacity of the surrounding soil underlying gripper can lead to insufficient propulsion, inability of excavation direction control and even shaft instability, therefore, it is necessary to study the ultimate bearing capacity of the surrounding soil underlying gripper. Based on the first mine-type shaft boring machine developed in China, the interaction between the gripper and soil is herein investigated by numerical simulation and the failure mode of the soil underlying gripper is determined to be shear-slip failure. Based on the failure mode simulated and the assumption made to treat the fracture face of surrounding soil under gripper as a combination of logarithmic helix and linear rotating surface, the stress distribution on the fracture face is analysed. Then, the formula of ultimate bearing capacity of surrounding soil underlying gripper is derived using the plastic limit equilibrium theory. Finally, the formula of ultimate bearing capacity is compared and analysed with the numerical simulation results to show its rationality. The results of this investigation can provide important guidance to the gripper design of shaft boring machines and stability evaluation of surrounding soil underlying shaft boring machine's gripper in different conditions. © 2020, Science Press. All right reserved.

引用

页码：227 / 236

页数：9

共 16 条

[1] LIU Zhi-qiang, Present status and the development orientation of rapid mine construction technology and equipment, Mine Construction Technology, 35, pp. 4-11, (2014)
[2] JING Guo-ye, LIU Zhi-qiang, HAN Bo, Research on shaft technology and equipment of mine shaft excavator, China Coal, 44, 5, pp. 65-70, (2018)
[3] TAN Hao, LIU Zhi-qiang, CHENG Shou-ye, Design on support system of MSJ5.8/1.6D mode mine shaft boring machine, Mine Construction Technology, 37, 3, pp. 44-48, (2016)
[4] JING Guo-ye, GAO Feng, Research on automatic rectifying-deviation system of MSJ5.8/1.6D shaft heading machine, Coal Science and Technology, 46, 12, pp. 27-34, (2018)
[5] TERZAGHI K, PECK R B., Soil mechanics in engineering practice, (1948)
[6] SARAMA S K., Stability analysis of embankment and slope, Geotechnique, 23, 3, pp. 423-433, (1979)
[7] DONALD I, CHEN W F., Slope stability analysis by an upper bound plasticity method, Canadian Geo-technical Journal, 34, 11, pp. 853-862, (1997)
[8] LUAN Mao-tian, ZHANG Qi-yi, YANG Qing, Et al., Upper bound limit analysis of bearing capacity of rectangular shallow footing on homogeneous clays, The Ocean Engineering, 5, 2, pp. 69-77, (2008)
[9] WANG Yan-song, ZHANG Hong-bin, Analysis and application of the calculation theory of carrying capacity of subgrades, Journal of Changchun University of Technology (Natural Science Edition), 26, 2, pp. 169-172, (2005)
[10] CAO Wen-gui, TAN Jian-hui, HU Wei-dong, Upper bound of ultimate bearing capacity for the reinforced grounds, Rock and Soil Mechanics, 39, 6, pp. 1955-1962, (2018)

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