Laboratory investigation of performance of a screen type debris-flow countermeasure

Yifru, Ashenafi Lulseged; Laache, Emilie; Norem, Harald; Nordal, Steinar; Thakur, Vikas

doi:10.1080/1023697x.2018.1462104

Cited by 14 publications

(4 citation statements)

References 40 publications

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“…As debris flows tend to consolidate rapidly, the residence time of the mixture in a storage container should be minimized to prevent separation of the solid and fluid phases, as this causes low test repeatability and gives rise to capillary stresses between soil grains (Song and Choi 2021). Some models include a mixer in the storage container (Ng et al 2022, Yifru et al 2018 to continuously disturb the solid-fluid mixtures and thereby hinder consolidation. Iverson (2015) noted that debris flows in the field are generally initiated from static sloping ground and in response to subtle and progressive changes in pore water pressures, which lead to force imbalances and slope instability, culminating in landslides (Iverson 2000).…”

Section: Unsteady Flume Modelsmentioning

confidence: 99%

Flume Modeling of Debris Flows

Choi,

Ng,

Liu

2024

Geoenvironmental Disaster Reduction

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Debris flows are complex mixtures of water and soil, which range from clay to boulder size, that surge downslope under the influence of gravity. Debris flows are unique compared to other types of landslides (e.g., rock avalanches; dry granular flows) because their dynamics are governed by both the soil grains and interstitial fluid. On one hand, debris flows may exhibit some features of dry granular flows, such as particle size segregation. On the other hand, contact and collisional grain stresses are strongly influenced by the viscosity and excess pressure of the interstitial fluid. Furthermore, debris flows travel over complex erodible boundaries and have been reported to reach volumes of up to 10 9 m 3 and travel kilometers in length. Evidently, the scale and dynamics of natural debris flows are complex and difficult to reproduce. One of the most common approaches to investigate the dynamics of debris flows is by conducting experiments, which provide idealized and high-quality evidence to evaluate theoretical and numerical models. This chapter provides an overview of the fundamental principles, scaling considerations, commonly adopted setups (e.g., flumes and geotechnical centrifuge), and the state-of-the-art in instrumentation and image analysis for modeling debris flows.

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Section: Unsteady Flume Modelsmentioning

confidence: 99%

Flume Modeling of Debris Flows

Choi,

Ng,

Liu

2024

Geoenvironmental Disaster Reduction

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“…To mitigate the potential destructiveness of these flow-like landslides, structural countermeasures are often used to reduce flow mobility or even retain the flow. There exist many different debris-resisting structures to cope with the threat related to debris avalanches and debris flows including artificial barriers Wendeler et al (2007), sabo dams Mizuyama (2008), check dams Popescu and Sasahara (2009), baffles Ng et al (2015), Geosynthetics-reinforced barriers Cuomo et al (2020), bottom drainage screen Yifru et al (2018).…”

Section: Reducing the Impact Of The Debris Avalanchementioning

confidence: 99%

“…The idea of installing bottom drainage screens along the propagation path of debris flows to reduce their impact was proposed by Hashimoto in Japan in the 1950s Kiyono et al (1986); Gonda (2009). Due to the effectiveness of this energy dissipating structure, several small-scale physical models have been conducted to have a better understanding of debris-flow screens and their mechanism including (i) the effects of different opening widths of permeable screens on the debris-flow run-out distance Gonda (2009), (ii) the effects of different bed sediments with different blocking and opening widths Kim (2013) and (iii) the effects of different location of debris flow screens, in the middle or at the end of propagation path, on the behaviour of debris flows Yifru et al (2018).…”

Section: Reducing the Impact Of The Debris Avalanchementioning

confidence: 99%

Two-phase SPH modelling of a real debris avalanche and analysis of its impact on bottom drainage screens

et al. 2021

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Rapid flow-like landslides, particularly debris flows and debris avalanches, cause significant economic damage and many victims worldwide every year. They are usually extremely fast with the capability of travelling long distances in short times, sweeping away everything in their path. The principal objective of this paper is to test the ability of the ‘GeoFlow-SPH’ two-phase model developed by the authors, to reproduce the complex behaviour of natural debris avalanches where pore-water pressure evolution plays a key role. To reach this goal, the model is applied to reproduce the complex dynamic behaviour observed in Johnsons Landing debris avalanche including the observed bifurcation caused by the flowing out of part of the moving mass from the mid-channel. Initial thickness deposit trim-line, distribution of deposit volume, and the average velocities were provided for this real case, making it an appropriate case to validate the developed model. The paper also contributes to evaluate the SPH-FD model’s potentialities to simulate the structural countermeasure, like bottom drainage screens, used to reduce the impact of debris flows. The analysis of the results shows the adequacy of the proposed model to solve this complicated geophysical problem.

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“…In the second simulation, the capacity of the proposed model was evaluated to reproduce a debris flow on a laboratory scale inclined channel, by comparing the numerical results with the measurements obtained from experiments and assessing the performance of the time-space evolution of pore-water pressure. The small scale laboratory test performed by Yifru at Trondheim (2019) [137] to illustrate the effect of the permeable debris flow rack and its working mechanism.…”

Section: Introductionmentioning

confidence: 99%

A two-phase SPH depth integrated model for debris flow propagation considering pore water pressure evolution

Tayyebi¹

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Laboratory investigation of performance of a screen type debris-flow countermeasure

Cited by 14 publications

References 40 publications

Flume Modeling of Debris Flows

Flume Modeling of Debris Flows

Two-phase SPH modelling of a real debris avalanche and analysis of its impact on bottom drainage screens

A two-phase SPH depth integrated model for debris flow propagation considering pore water pressure evolution

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