Studying Scour Hole Development around Rectangular Bridge Piers

A new type of collar, the hooked-collar, was studied through experiments and numerical methods. Tests were conducted using a hooked collar of a width of 1.25b and a height of 0.25b, where b is the bridge-pier width. The hooked-collar efficiency was evaluated by testing different hooked-collar placements within the bridge-pier, which were compared to the bridge-pier without any collar. A double hooked-collar configuration, one placed at the bed level and the other buried 0.25b, was the most efficient at reducing the scour hole. In other cases, a hooked-collar positioned 0.25b above the bed slightly reduced the scour hole and had similar scour patterns when compared to the pier without the hooked-collar. The flow fields along the vertical symmetrical plane in the experiments are also presented. Laboratory experiments and numerical tests show that maximal downflow is highly reduced along with a corresponding decrease in horseshoe vortex strength for the experiments with the hooked-collar, compared to cases without the hooked-collar. The flow fields reveal that the maximum turbulent kinetic energy decreases with the installation of the hooked-collar.

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Remote Real-time Riprap Protection Erosion AssessmenT on large rivers

10.5194/egusphere-egu2020-1933 ◽

2020 ◽

Author(s):

Gordon Gilja ◽

Antonija Cikojević ◽

Kristina Potočki ◽

Matej Varga ◽

Nikola Adžaga

Keyword(s):

Real Time ◽

Large Rivers ◽

Bridge Piers ◽

Hybrid Modelling ◽

Field Surveys ◽

Scour Monitoring ◽

Scour Hole ◽

Riprap Protection ◽

Model Phase ◽

Modelling Approach

Large number of bridges in Europe is at the end of their life span, while the frequency of occurrence for extreme climatic events, driven by climate change, is increasing. Floods influence morphodynamic changes in the riverbed, such as scouring of the riverbed next to the bridge substructure, that can undermine the overall stability of the bridge. Placement of riprap protection around bridge piers is an approach that doesn&#8217;t solve scouring problem, it rather displaces the scour hole elsewhere in the river channel, where its location is unknown because it is formed in the interaction between the flow and the structure, in site-specific conditions. Traditional approach to scour monitoring is effective only if surveys are conducted during the flood conditions, while the data acquired post-flood can underestimate the full potential of flood hazard. Detailed field surveys of hydraulic parameters during floods are essential in the understanding of morphodynamic evolution of the river channel, but are often scarce because they are time-consuming and require extensive resources (e.g. the survey equipment). Therefore, the majority of research was conducted using hydraulic flumes where both flow and the riverbed conditions are idealized&#160;The goal of the R3PEAT project (Remote Real-time Riprap Protection Erosion AssessmenT on large rivers) is to bridge the gap between the real-time scour hole development and flow environment through development of real-time scour monitoring system. The research focus of the project is investigation of scouring processes next to the riprap protection around bridge piers - existing structures whose stability and safety are unknown in the hydraulic environment under the influence of climate change. Research methodology combines experimental investigations on scaled physical model (Phase I) with 3D numerical model (Phase II) into hybrid modelling approach, calibrated and validated with field surveys. The research objectives of the project are: (1) develop ScourBuoy prototype (2); calibrate the physical model with field surveys; (3) improve existing empirical equations for equilibrium scour hole development using hybrid modelling approach; (4) investigate the dependence between turbulent flow characteristics and temporal scour hole development and (5) investigate dependence between turbulent conditions and incipient motion of sediment particles. The impact of the proposed project on the bridge management systems is expected through the development of a practical remote real-time system for erosion estimation around the riprap protection on large rivers that can be basis for the real-time decision support system.Acknowledgment: This work has been supported in part by Croatian Science Foundation under the project R3PEAT (UIP-2019-04-4046)

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Experimental Investigation of the Debris Configurations Effects on the Scour Hole Morphology at Circular Bridge Piers

IOP Conference Series Materials Science and Engineering ◽

10.1088/1757-899x/737/1/012157 ◽

2020 ◽

Vol 737 ◽

pp. 012157

Author(s):

Mahmoud Saleh Al-Khafaji ◽

Aysar Tuama Al-Awadi

Keyword(s):

Experimental Investigation ◽

Bridge Piers ◽

Scour Hole

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CFD prediction of local scour hole around bridge piers

Journal of Central South University ◽

10.1007/s11771-012-1001-x ◽

2012 ◽

Vol 19 (1) ◽

pp. 273-281 ◽

Cited By ~ 10

Author(s):

Zhi-wen Zhu ◽

Zhen-qing Liu

Keyword(s):

Local Scour ◽

Bridge Piers ◽

Scour Hole

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Application of neuro-fuzzy model to estimate the characteristics of local scour downstream of stilling basins

Journal of Hydroinformatics ◽

10.2166/hydro.2009.069 ◽

2009 ◽

Vol 12 (2) ◽

pp. 201-211 ◽

Cited By ~ 14

Author(s):

J. Farhoudi ◽

S. M. Hosseini ◽

M. Sedghi-Asl

Keyword(s):

Fuzzy Model ◽

Local Scour ◽

Bridge Piers ◽

Type I ◽

Effective Parameters ◽

Promising Alternative ◽

Neuro Fuzzy ◽

Scour Hole ◽

Stilling Basins ◽

Tail Water

The local scour phenomenon in the vicinity of bridge piers and stilling basins has received considerable attraction from designers due to its consequences which may endanger these structures. Various factors govern the pattern of scour evolution which results in the complexity of this phenomenon. Many researchers indicated that the use of fuzzy logic in modeling this phenomenon could be a promising alternative to reflect the vagueness and ambiguity of effective parameters. The aim of this study is to investigate the performance of a neuro-fuzzy model based on Takagi and Sugeno's theory in estimating the maximum depths, pattern and time evolution of scour hole downstream of a stilling basin of U.S.B.R. type I. The investigation was conducted under various discharges, tail-water depths (low, balanced and high), different bed materials and model sizes. The characteristics of the equilibrium state of the scour phenomenon as well as the time to reach the maximum scour depth were considered. The results showed a significant conformity between estimated and experimental data which recommends an acceptable outcome using a neuro-fuzzy model to forecast the properties of scour hole downstream of stilling basins. This would contribute to predicting the design geometry of stilling pools and taking the appropriate precautions to protect the downstream channel bed.

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A Study on Interaction between Overfall Types and Scour at Bridge Piers with a Moving-Bed Experiment

Water ◽

10.3390/w13020152 ◽

2021 ◽

Vol 13 (2) ◽

pp. 152

Author(s):

Wei-Lin Lee ◽

Chih-Wei Lu ◽

Chin-Kun Huang

Keyword(s):

Large Scale ◽

River Flow ◽

Extreme Event ◽

Bridge Pier ◽

Bridge Piers ◽

Flow Conditions ◽

Moving Bed ◽

Directional Flow ◽

Scour Hole ◽

Additional Protection

River slopes can be changed due to an extreme event, e.g., a large-scale earthquake. This can uplift a riverbed greatly and thereby change the behavior of the river flow into a free or submerged overfall. Corresponding damage, including extreme erosion, on bridge piers located in the river can take place due to the aforementioned flow conditions. A reconstructed bridge pier in the same location would also experience a similar impact if the flow condition is not changed. It is important to identify these phenomena and research the mechanism in the interaction between overfall types and scour at bridge piers. Therefore, this paper is aimed at studying a mechanism of free and submerged overfall flow impacts on bridge piers with different distances by a series of moving-bed experiments. The experiment results showed clearly that bridge pier protection requires attention particularly when the pier is located in the maximum scour hole induced by the submerged overfall due to the z directional flow eddies. In many other cases, such as when the location of the bridge pier was at the upstream slope of a scour hole induced by a flow drop, a deposition mound could be observed at the back of the pier. This indicates that, while a pier is at this location, an additional protection takes place on the bridge pier.

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Improving the 2D Numerical Simulations on Local Scour Hole around Spur Dikes

Water ◽

10.3390/w13111462 ◽

2021 ◽

Vol 13 (11) ◽

pp. 1462

Author(s):

Chung-Ta Liao ◽

Keh-Chia Yeh ◽

Yin-Chi Lan ◽

Ren-Kai Jhong ◽

Yafei Jia

Keyword(s):

Numerical Simulation ◽

Three Dimensional ◽

Local Scour ◽

Bridge Piers ◽

Scour Depth ◽

Foundation Design ◽

Mobile Bed ◽

Scour Hole ◽

Scour Holes ◽

Spur Dikes

Local scour is a common threat to structures such as bridge piers, abutments, and dikes that are constructed on natural rivers. To reduce the risk of foundation failure, the understanding of local scour phenomenon around hydraulic structures is important. The well-predicted scour depth can be used as a reference for structural foundation design and river management. Numerical simulation is relatively efficient at studying these issues. Currently, two-dimensional (2D) mobile-bed models are widely used for river engineering. However, a common 2D model is inadequate for solving the three-dimensional (3D) flow field and local scour phenomenon because of the depth-averaged hypothesis. This causes the predicted scour depth to often be underestimated. In this study, a repose angle formula and bed geometry adjustment mechanism are integrated into a 2D mobile-bed model to improve the numerical simulation of local scour holes around structures. Comparison of the calculated and measured bed variation data reveals that a numerical model involving the improvement technique can predict the geometry of a local scour hole around spur dikes with reasonable accuracy and reliability.

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Experimental Characterization of the Flow Field around Oblong Bridge Piers

Fluids ◽

10.3390/fluids6110370 ◽

2021 ◽

Vol 6 (11) ◽

pp. 370

Author(s):

Ana Margarida Bento ◽

Teresa Viseu ◽

João Pedro Pêgo ◽

Lúcia Couto

Keyword(s):

Flow Field ◽

Large Scale ◽

Bridge Pier ◽

Bridge Piers ◽

Shear Stresses ◽

Velocity Measurements ◽

Bridge Foundations ◽

Scour Hole ◽

Movable Bed

The prediction of scour evolution at bridge foundations is of utmost importance for engineering design and infrastructures’ safety. The complexity of the scouring inherent flow field is the result of separation and generation of multiple vortices and further magnified due to the dynamic interaction between the flow and the movable bed throughout the development of a scour hole. In experimental environments, the current approaches for scour characterization rely mainly on measurements of the evolution of movable beds rather than on flow field characterization. This paper investigates the turbulent flow field around oblong bridge pier models in a well-controlled laboratory environment, for understanding the mechanisms of flow responsible for current-induced scour. This study was based on an experimental campaign planned for velocity measurements of the flow around oblong bridge pier models, of different widths, carried out in a large-scale tilting flume. Measurements of stream-wise, cross-wise and vertical velocity distributions, as well as of the Reynolds shear stresses, were performed at both the flat and eroded bed stages of scouring development with a high-resolution acoustic velocimeter. The time-averaged values of velocity and shear stress are larger in the presence of a developed scour hole than in the corresponding flat bed configuration.

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