Face stability of EPB shield tunnels in multilayered ground with soft sand lying on hard rock considering dynamic excavation process: A DEM study

•The dynamic excavation process of EPB shield tunnel in multilayered ground is simulated.•The influence of underlying hard rock on the stability of overlying soft sand is revealed.•Characteristics of the tunnel face failure mechanism in multilayered ground is obtained. This paper aims at studying th...

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Bibliographic Details
Published in:Tunnelling and underground space technology 2022-02, Vol.120, p.104268, Article 104268
Main Authors: Wang, Jun, Lin, Guojin, Xu, Guowen, Wei, Yanqing, Li, Shiqi, Tang, Xie, He, Chuan
Format: Article
Language:English
Subjects:
Collapse
Cutting
Diameters
Discrete element method
Discrete element method (DEM)
Dynamic excavation process
Dynamic stability
Earth pressure
EPB shield tunnel
Excavation
Face stability
Failure
Multilayered ground
Pressure effects
Sand
Soil dynamics
Soil stability
Soils
Systems stability
Tunneling shields
Tunnels
Underground construction
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Summary:•The dynamic excavation process of EPB shield tunnel in multilayered ground is simulated.•The influence of underlying hard rock on the stability of overlying soft sand is revealed.•Characteristics of the tunnel face failure mechanism in multilayered ground is obtained. This paper aims at studying the face stability of earth pressure balanced (EPB) shield tunnels in multilayered ground with soft sand lying on hard rock considering dynamic excavation process. The analysis was performed using three dimensional discrete element method (DEM). The present work has two advantages: (1) it reveals the influence of soil disturbance induced by dynamic cutting process on tunnel stability in multilayered ground; (2) it reveals the influence of soil retaining provided by cutterhead panel on tunnel face stability in multilayered ground. Results show that tunnel face collapse undergoes two stages. The underlying hard rock restricts the movement of overlying soft soil, and face failure happens more abruptly with decreasing η (η = a/D. a = height of soft sand within tunnel cross section; D = tunnel diameter). The normalized limit support pressure pf/γD (pf = limit support pressure; γ = soil unit weight) obtained from this paper is larger than that of existing research, i.e. existing research underestimate the limit support pressure. The weakening effect of cutterhead dynamic cutting process on face stability is larger than the strengthening effect of cutterhead panel retaining on face stability. The difference generally increases with increasing C/D (C = tunnel cover depth) and η. Partial collapse occurs in multilayered ground with soft sand lying on hard rock. C/D mainly influences the shape of the failure zone, and η mainly determines the size of the failure zone.
ISSN:0886-7798
1878-4364
DOI:10.1016/j.tust.2021.104268