Riverine flow and floating wooden debris interaction with an arch bridge: flume experiments

Eda Majtan; Lee Cunningham; Benedict D. Rogers

doi:10.1080/00221686.2024.2437688

Riverine flow and floating wooden debris interaction with an arch bridge: flume experiments

Eda Majtan, Lee Cunningham, Benedict D. Rogers

Civil Engineering and Management

University of Liverpool

Research output: Contribution to journal › Article › peer-review

Abstract

Masonry arch bridges (MABs) are vulnerable to flood effects. Whilst previous studies have focused on scour around bridge piers, very little investigation has been conducted on the flood effects on the superstructure of MABs. This paper is the first experimental study to provide an understanding of this complex phenomenon. The generation of detailed pressure–time and force–time histories on MABs with different submergence ratios and debris orientations enables useful insights into the physics involved while providing critical data for the validation of future numerical models. The results without floating debris indicate that hydrodynamic pressures and forces were captured with high precision, while it decreased with a coefficient of variation of 34.54% close to the free surface. In the cases with debris, multiple impact pressures and forces were obtained. Furthermore, a 0° orientation is more prone to debris accumulation and associated afflux at the bridge superstructure compared to a 90° situation.

Original language	English
Pages (from-to)	542-559
Journal	Journal of Hydraulic Research
Volume	62
Issue number	6
DOIs	https://doi.org/10.1080/00221686.2024.2437688
Publication status	Accepted/In press - 29 Nov 2024

Keywords

Debris impact
discrete wavelet analysis
fluid-structure interaction
river hydrodynamics
masonry arch bridges

Research Beacons, Institutes and Platforms

Global inequalities

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1080/00221686.2024.2437688Licence: CC BY

4 Article
3 Conference contribution
1 Abstract

Multiphysics Coupling Using SPH for Coastal Structures Subject to Tsunami-Driven Hydrodynamic and Debris Impact Loads
Ishiki, K., Cunningham, L. & Rogers, B. D., 1 Jan 2025, In: Journal of Waterway, Port, Coastal, and Ocean Engineering. 151, 1, p. 1-18
Research output: Contribution to journal › Article › peer-review

Open Access
File
10 Downloads (Pure)
Flood Resilience in Pole-Mounted Substations: Structural Fragility Assessment
Li, W., Cunningham, L., Schultz, D., Mander, S., Gan, C. K. & Panteli, M., 6 Jun 2024.
Research output: Contribution to conference › Abstract › peer-review

Open Access
Numerical study on the structural response of a masonry arch bridge subject to flood flow and debris impact
Majtan, E., Cunningham, L. & Rogers, B. D., 1 Feb 2023, In: Structures. 48, p. 782-797 16 p.
Research output: Contribution to journal › Article › peer-review

Open Access

Cite this

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title = "Riverine flow and floating wooden debris interaction with an arch bridge: flume experiments",

abstract = "Masonry arch bridges (MABs) are vulnerable to flood effects. Whilst previous studies have focused on scour around bridge piers, very little investigation has been conducted on the flood effects on the superstructure of MABs. This paper is the first experimental study to provide an understanding of this complex phenomenon. The generation of detailed pressure–time and force–time histories on MABs with different submergence ratios and debris orientations enables useful insights into the physics involved while providing critical data for the validation of future numerical models. The results without floating debris indicate that hydrodynamic pressures and forces were captured with high precision, while it decreased with a coefficient of variation of 34.54% close to the free surface. In the cases with debris, multiple impact pressures and forces were obtained. Furthermore, a 0° orientation is more prone to debris accumulation and associated afflux at the bridge superstructure compared to a 90° situation.",

keywords = "Debris impact, discrete wavelet analysis, fluid-structure interaction, river hydrodynamics, masonry arch bridges",

author = "Eda Majtan and Lee Cunningham and Rogers, {Benedict D.}",

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doi = "10.1080/00221686.2024.2437688",

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TY - JOUR

T1 - Riverine flow and floating wooden debris interaction with an arch bridge: flume experiments

AU - Majtan, Eda

AU - Cunningham, Lee

AU - Rogers, Benedict D.

PY - 2024/11/29

Y1 - 2024/11/29

N2 - Masonry arch bridges (MABs) are vulnerable to flood effects. Whilst previous studies have focused on scour around bridge piers, very little investigation has been conducted on the flood effects on the superstructure of MABs. This paper is the first experimental study to provide an understanding of this complex phenomenon. The generation of detailed pressure–time and force–time histories on MABs with different submergence ratios and debris orientations enables useful insights into the physics involved while providing critical data for the validation of future numerical models. The results without floating debris indicate that hydrodynamic pressures and forces were captured with high precision, while it decreased with a coefficient of variation of 34.54% close to the free surface. In the cases with debris, multiple impact pressures and forces were obtained. Furthermore, a 0° orientation is more prone to debris accumulation and associated afflux at the bridge superstructure compared to a 90° situation.

AB - Masonry arch bridges (MABs) are vulnerable to flood effects. Whilst previous studies have focused on scour around bridge piers, very little investigation has been conducted on the flood effects on the superstructure of MABs. This paper is the first experimental study to provide an understanding of this complex phenomenon. The generation of detailed pressure–time and force–time histories on MABs with different submergence ratios and debris orientations enables useful insights into the physics involved while providing critical data for the validation of future numerical models. The results without floating debris indicate that hydrodynamic pressures and forces were captured with high precision, while it decreased with a coefficient of variation of 34.54% close to the free surface. In the cases with debris, multiple impact pressures and forces were obtained. Furthermore, a 0° orientation is more prone to debris accumulation and associated afflux at the bridge superstructure compared to a 90° situation.

KW - Debris impact

KW - discrete wavelet analysis

KW - fluid-structure interaction

KW - river hydrodynamics

KW - masonry arch bridges

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DO - 10.1080/00221686.2024.2437688

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Riverine flow and floating wooden debris interaction with an arch bridge: flume experiments

Abstract

Keywords

Research Beacons, Institutes and Platforms

UN SDGs

Access to Document

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Research output

Multiphysics Coupling Using SPH for Coastal Structures Subject to Tsunami-Driven Hydrodynamic and Debris Impact Loads

Flood Resilience in Pole-Mounted Substations: Structural Fragility Assessment

Numerical study on the structural response of a masonry arch bridge subject to flood flow and debris impact

Cite this