Probabilistic Analysis of Tunnel Liner Performance Using Random Field Theory

Yu, Xin; Cheng, Jinguo; Cao, Chunhui; Li, Erqiang; Feng, Jili

doi:10.1155/2019/1348767

Cited by 8 publications

(5 citation statements)

References 56 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Gong et al (2018) presents a probabilistic analysis based on a random field generation for a longitudinal analysis for a bored tunnel. For a bored-tunnel section, a 2D plain strain approach including a random field generation is presented by Yu et al (2019) in which the reliability of the tunnel lining is validated.…”

Section: Literature Overviewmentioning

confidence: 99%

The Influence of Spatial Variation on the Design of Foundations of Immersed Tunnels: Advanced Probabilistic Analysis

't Hart,

Morales-Napoles,

Jonkman

2023

Preprint

View full text Add to dashboard Cite

Section: Literature Overviewmentioning

confidence: 99%

The Influence of Spatial Variation on the Design of Foundations of Immersed Tunnels: Advanced Probabilistic Analysis

't Hart,

Morales-Napoles,

Jonkman

2023

Preprint

View full text Add to dashboard Cite

“…To this end, recently, the advancements in computational tools have also facilitated the analysis of deep excavations using probabilistic numerical approaches. However, the influence of soil spatial variability has been extensively studied in various geotechnical design scenarios involving slopes, gravity retaining walls, tunnels and shallow foundations [5][6][7][8][9][10][11]. Despite this, there are insufficient amount of studies focusing on the impact of spatial variation, particularly in relation to probabilistic analysis of deep excavations.…”

Section: Introductionmentioning

confidence: 99%

The Effect of Incorporating Vertical Spatial Variability on the Probabilistic Analysis of a Deep Excavation: A Case Study

KORKUT,

AKBAŞ

2023

Politeknik Dergisi

View full text Add to dashboard Cite

This study explores the impact of including the vertical spatial variability in effective stress friction angle of clay on the probabilistic analysis of deep excavations. The proposed methodology is demonstrated and verified by conducting random finite element modeling (RFEM) of an instrumented deep excavation project situated in Ankara, Turkey. The excavation has a depth of 20 meters and is supported by six levels of pre-stressed ground anchors. To simulate the vertical spatial variability of effective stress friction angle in the clay, Monte Carlo simulation method and the random field theory are employed. The simulated parameters are then inserted into the finite element model via Python programming language to analyze the probabilistic distribution of lateral deflections and bending moments in the drilled shaft wall. The results obtained from the Monte Carlo simulations reveal that the incorporation and selected value of spatial variability significantly impacts the resulting lateral movements, bending moments, and the probability of failure of the system.

show abstract

“…In recent years, the variability of mechanical properties in space has received much attention. For example, Yu et al [8] took advantage of stochastic numerical modeling to study the performance of tunnel linings and concluded that this procedure could lead to a more equitable and economical design. Besides, the well-known Monte Carlo Simulation (MCS) can be combined with numerical analysis to introduce spatially variable soil properties described by random fields [9,10].…”

Section: Introductionmentioning

confidence: 99%

Effect of spatial variability of creep rock on the stability of a deep double-lined drift

Tuyền¹,

Hoxha

et al. 2022

STCE

View full text Add to dashboard Cite

This work aims at investigating the effect of aleatoric uncertainty of creep rock properties on the stability of an underground structure. This uncertainty relates to the spatial variability of the mechanical parameters representing the time-dependent behavior of geological rock formation due to the change in its mineralogy. The chosen methodology consists of representing the aleatoric uncertainty of rock properties by random fields, written as correlation functions with respect to the spatial correlation length. The adaptation of the well-known Expansion Optimal Linear Estimationmethod (EOLE) is performed to account for the cross-correlation of the random fields of the viscoplastic parameters of the host rock. Then, the Kriging-based reliability analysis is undertaken with respect to the discretized random fields, which allows elucidating the effect of spatial variability. As an application, the proposed approach is chosen to study the stability in the long-term of a deep double-lined drift within the geological disposal facilities (Cigeo project) conducted by the French National Radioactive Waste Management Agency (Andra). The drift will be excavated in Callovo-Oxfordian (COx) claystone (if the Cigeo project is licensed), considered as a potential host rock for the deep geological nuclear waste disposal in France. The results show that the chosen Kriging metamodel for the reliability analysis can be appropriate for the case of high correlation length represented by a moderate number of random variables (up to about 50) after the discretization of random fields. Further, the consideration of aleatoric uncertainty exhibits a lower probability of exceedance in comparison with the case where spatial variability is ignored. Still, more investigations need to be conducted in the future to conclude this observation.

show abstract

Probabilistic Analysis of Tunnel Liner Performance Using Random Field Theory

Cited by 8 publications

References 56 publications

The Influence of Spatial Variation on the Design of Foundations of Immersed Tunnels: Advanced Probabilistic Analysis

The Influence of Spatial Variation on the Design of Foundations of Immersed Tunnels: Advanced Probabilistic Analysis

The Effect of Incorporating Vertical Spatial Variability on the Probabilistic Analysis of a Deep Excavation: A Case Study

Effect of spatial variability of creep rock on the stability of a deep double-lined drift

Contact Info

Product

Resources

About