Hazards due to large wood accumulations: Local scour and backwater rise

Schalko, Isabella; Schmocker, Lukas; Weitbrecht, Volker; Boes, Robert M.

doi:10.1051/e3sconf/20184002003

Cited by 4 publications

(2 citation statements)

References 14 publications

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“…(2014b) refer that LW pieces oriented parallel and oblique to the flow direction are transported in the line of maximum velocity in their original orientation. Schalko (2018) demonstrated that the deposition probability was six times lower for those pieces transported in parallel orientation with the flow direction. In the studied river reaches, the LW dimensions suggest the fast onset of LW transport; however, their prevailing orientation and log‐log and log‐living tree interactions in the channel and inundated floodplain may be limiting factors for long transport trajectories.…”

Section: Discussionmentioning

confidence: 99%

Numerical Modeling of Potential Large Wood Entrainment in Rivers: Application of Hybrid Modeling in the Inter‐Dam Reach of the Dyje River, Czechia

Hlavňa,

Máčka,

Záthurecký

2024

Water Resources Research

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Mobilization of large wood in river channels during floods represents a hazardous factor, augmenting flood risk and endangering infrastructures such as bridges, weirs, and reservoir dams. A hybrid modeling approach combining numerical models with field‐based surveys has been recently used to elucidate the processes of LW entrainment and deposition in rivers. We used two‐dimensional hydraulic modeling performed in HEC‐RAS to simulate LW entrainment in two valley bottom segments of the Dyje River, Czechia, where LW deposition is a significant hazard to the dam of the downstream Znojmo reservoir. We surveyed all LW pieces in the inundation area of the 2002 extreme (>Q100) flood and simulated their entrainment for eight flood scenarios (1–100‐year recurrence interval). We used the equations of Braudrick and Grant (2000, https://doi.org/10.1029/1999WR900290) to calculate the LW entrainment threshold; we introduced coefficient k accounting for the incomplete submersion of LW pieces resting on an inclined surface into the original equations. Four entrainment categories — stable, wetted stable, wetted buoyant, and wetted entrained — were defined, and the proportion of LW pieces in each category was calculated for the flood scenarios. We found marked differences in entrainment categories for respective flood scenarios between the two valley segments. These were attributed to the differences in pieces' dimensions, their spatial distribution within the inundation area, and valley‐bottom topography, which affects the hydraulic conditions for a given discharge. The presented approach enables the calculation of the LW quantity potentially mobilized by the flood of a certain magnitude indicating the degree of potential risk for the infrastructures located downstream.

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Section: Discussionmentioning

confidence: 99%

Numerical Modeling of Potential Large Wood Entrainment in Rivers: Application of Hybrid Modeling in the Inter‐Dam Reach of the Dyje River, Czechia

Hlavňa,

Máčka,

Záthurecký

2024

Water Resources Research

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“…Despite such benefits, trees that fall from forest slopes after heavy rainfall become LW that accumulates in rivers, posing hazards to people and property, e.g., [6]. LW disasters caused by heavy rainfall, occasionally accompanied by sediment-related disasters, have been reported in many countries [7][8][9]. In Japan, LW disasters occurred in Asakura City (Fukuoka Prefecture) and Hita City (Oita Prefecture) during heavy rainfall in 2017 in northern Kyushu [10], and in Hiroshima City and Kure City (both in Hiroshima Prefecture) during heavy rainfall in 2018 [11] (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

Flume Experiments Evaluating the Efficacy of a Large Wood Trap Featuring Horizontal Rods

Furukawa¹,

Tsutsumi

Muto³

et al. 2021

Water

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Large wood (LW) disasters, which often accompany sediment-related disasters, occur worldwide. To prevent and mitigate such disasters, we developed a unique LW trap featuring horizontal rods aligned with the flow. When LW enters the trap, it is scooped up by the rods and thus separated from water and sediment. We explored trapping efficacy using a flume of slope 0.087. Water circulated at a constant rate of 1.8 L/s, LW was added to the flow, and the trapping rates were measured. We focused on the relative wood length (Lw) with respect to the horizontal rod spacing (Sr), the number of LW units supplied, and the supply rate. A longer relative length (Lw/Sr) of LW was associated with a higher trapping rate. The trapping rate was also high when the LW number or supply rate was high. The critical Lw/Sr value was 1.5; below this value, LW was not trapped. This study yields the basic information needed to design traps featuring horizontal rods to mitigate LW-related disasters.

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Experimental analysis of open check dams and protection bars against debris flows and driftwood

Rossi

Armanini

2019

Environ Fluid Mech

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Hazards due to large wood accumulations: Local scour and backwater rise

Cited by 4 publications

References 14 publications

Numerical Modeling of Potential Large Wood Entrainment in Rivers: Application of Hybrid Modeling in the Inter‐Dam Reach of the Dyje River, Czechia

Numerical Modeling of Potential Large Wood Entrainment in Rivers: Application of Hybrid Modeling in the Inter‐Dam Reach of the Dyje River, Czechia

Flume Experiments Evaluating the Efficacy of a Large Wood Trap Featuring Horizontal Rods

Experimental analysis of open check dams and protection bars against debris flows and driftwood

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