Influence of pipe jacking excavation in overlying quicksand layer on surface settlement and numerical analysis

Peng Qi; Yi Huang; Lijuan Cheng; Yang Shen; Ru Yan

doi:10.54097/hset.v18i.2518

Authors

Peng Qi
Yi Huang
Lijuan Cheng
Yang Shen
Ru Yan

DOI:

https://doi.org/10.54097/hset.v18i.2518

Keywords:

Quicksand formation, Pipe jacking excavation, Grouting reinforcement, Surface subsidence

Abstract

The cause of quicksand in soil depends on the nature of soil. Under the action of permeability, quicksand is easy to occur when the pore ratio of soil is large, the water content is large, the clay content is small, the silt content is large, the permeability coefficient is small and the drainage performance is poor. Therefore, quicksand phenomenon is easy to occur in fine sand, silt and loam, but whether quicksand phenomenon occurs or not also depends on certain external conditions, that is, the hydrodynamic pressure (permeability) generated by the seepage of groundwater in the soil. When the upward seepage force of unit granular soil is greater than or equal to its own gravity, the soil will suspend and move. In the process of underground engineering construction, if the problem of quicksand is not solved, the structure will displace with the flow of sand layer, which will change the bearing layer of the foundation and do great harm to the structure. This phenomenon should be eliminated. Practice shows that many accidents of underground structures are related to quicksand caused by the change of seepage conditions during construction. The disturbance of soil in pipe jacking construction is the fundamental cause of soil deformation. It destroys the original natural equilibrium state of soil, changes the stress-strain state of soil, and makes the undisturbed soil experience complex stress paths such as extrusion, shear and deformation. In this paper, a numerical model is established to analyze the surface settlement trend of pipe jacking in quicksand covered stratum, and the methods of grouting behind pipe jacking wall and excavation surface stability measures are verified to control the settlement measures in the construction process.

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References

Zhang Baisheng, Yang Zhiping, Yang Xuming, Zhang Shuai, Lin Jia. Presplit Blasting Technique in Treating Hard Overlying Strata: From Numerical Simulation to Field Practice[J]. Advances in Civil Engineering, 2021.

Zhang Hao, Li Tingchun, Wu Shuai et al. A study of innovative cut blasting for rock roadway excavation based on numerical simulation and field tests[J]Tunnelling and Underground Space Technology incorporating Trenchless Technology Research, 2022, 119.

Hao Jianchi, Ren Lifeng, Wen Hu et al. Experimental Study of Gangue Layer Weakening with Deep-Hole Presplitting Blasting[J] Shock and Vibration, 2021, 2021.

H.G. Naidu, R.K. Singhal Experience with cast blasting in Canadian surface coal mines[J] International Journal of Mining, Reclamation and Environment, 1989, 3(1).

Yong Wu, Wu Yong, Dai Yichang, Wang Shuaishuai, Wu Bo, Xu Shixiang, Wei Han. Analysis of Mutual Influence on Blasting Construction of Urban Shallow-buried Small Spacing Tunnels[J]. IOP Conference Series: Earth and Environmental Science, 2020, 525(1):

Wen-long Li; Xuan-ke Li; Ke Shen; Hui-tao Xu; Jian-guang Guo; Yong Wu Preparation and characterization of graphitized polyimide film/epoxy resin composites with high thermal conductivities [J] Carbon, 2022.

Yong Wu; Wei Li; Xiaoming Fan; Binjun Wang Entity-Context and Relation-Context Combined Knowledge Graph Embeddings [J] Arabian Journal for Science and Engineering, 2021.

Yong Wu; Xinpo Li; Lei Zhu Fracture mechanism of rock collapse in the freeze–thaw zone of the eastern Sichuan–Tibet Mountains under seasonal fluctuating combinations of water and heat [J] Natural Hazards, 2021.

Yuncan Chen; Xin Huang; Yingying Xu; Jianglian Li; Ruizhi Lai; Mei Guan; Yong Wu Ru (II)-Catalyzed C–H Activation Reaction between 2-Phenylquinazolinone and Vinylene Carbonate [J] SYNLETT, 2021.

Xiaoming Guan, Xuchun Wang, Zhen Zhu, Liang Zhang, Hongxian Fu. Ground Vibration Test and Dynamic Response of Horseshoe-shaped Pipeline During Tunnel Blasting Excavation in Pebbly Sandy Soil[J]. Geotechnical and Geological Engineering, 2020(prepublish).

Seong-Seung Kang, Hyongdoo Jang. A case study on tunnel blasting design evaluation considering blast damage zone[J]. Science and Technology of Energetic Materials, 2020, 81(No.4).

Zihan Liu, Nan Jiang, Jinshan Sun, Yuqing Xia, Guopeng Lyu. Influence of tunnel blasting construction on adjacent highway tunnel: A case study in Wuhan, China[J]. International Journal of Protective Structures, 2020, 11(3).

Xiaoming Guan, Liang Zhang, Yuwen Wang, Hongxian Fu, Jianyong An. Velocity and stress response and damage mechanism of three types pipelines subjected to highway tunnel blasting vibration[J]. Engineering Failure Analysis, 2020, 118.

Xiaoxu Tian, Zhanping Song, Junbao Wang. Study on the propagation law of tunnel blasting vibration in stratum and blasting vibration reduction technology[J]. Soil Dynamics and Earthquake Engineering, 2019, 126(C).

Nan Jiang, Tan Gao, Chuanbo Zhou, Xuedong Luo. Safety assessment of upper buried gas pipeline under blasting vibration of subway tunnel: a case study in Beijing subway line[J]. Journal of Vibroengineering, 2019, 21(4).