Flapping dynamics of a flexible membrane attached to the leading edge of a forward-facing step

Liu, Zhiwei; Wang, Hanfeng; Li, Jiaxuan; Li, Huan; Zhao, Chongyu

doi:10.1063/5.0211188

Physics of Fluids

2024

DOI: 10.1063/5.0211188

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Flapping dynamics of a flexible membrane attached to the leading edge of a forward-facing step

Zhiwei Liu,

Hanfeng Wang,

Jiaxuan Li

et al.

Abstract: The flapping dynamics of a flexible membrane (FM) and its effect on the flow fields over and pressure fluctuations on a forward-facing step (FFS) have been investigated experimentally. The two-dimensional FM with 40 mm in length and 0.15 mm in thickness was vertically attached to the leading edge of a FFS with 40 mm in height. The deformation of the flapping FM was recorded by a high-speed camera. Velocity data in the vertical central plane and the pressure fluctuations on the step surface were measured by pla… Show more

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2024

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Cited by 2 publications

References 47 publications

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Numerical simulation study on the effect of porosity on the flapping characteristics of perforated flags in different flow environments

Zhao,

Hu,

2024

Physics of Fluids

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The flapping characteristics of perforated flags with various porosities in different flow environments are studied using XFlow-Abaqus co-simulation. It is proved that flapping characteristics significantly correlate with flag porosity in different flow environments. Specifically, as the flag porosity increases, the flapping speed and vortex strength decrease monotonically. Further study of the influence of perforated flags on the flow structures surrounding a square cylinder revealed that different flag porosities lead to different levels of flow control. As the flag porosity increases, the flag's modulation weakens, the average drag on the square cylinder rises, and the influence of the Kármán vortex street becomes more significant. The flag-induced vortices can generate a high-pressure zone on the rear side of the square cylinder's top surface, leading to a decrease in the average lift on the square cylinder. It is notable that flags with different porosities generate vortices at different flapping states, which results in phase differences between the lift on the square cylinder and the flag. Finally, the study discusses the peaks of the Reynolds stress in the x- and y-directions, which delineate the boundary of the recirculation zone and reflect force fluctuations on the flag and the square cylinder, respectively.

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Numerical simulation study on the effect of porosity on the flapping characteristics of perforated flags in different flow environments

Zhao,

Hu,

2024

Physics of Fluids

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A novel strategy for mitigating the vortex-induced vibration of long-span bridges by using flexible membranes

Xu,

Wang,

Huang

et al. 2024

Advances in Structural Engineering

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The structural damping of a long-span bridge girder after completion is difficult to predict accurately in the design stage, and could be obviously lower than the value suggested by the code of wind-resistance design, which could lead to large-amplitude vortex-induced vibration (VIV) of the girder after completion. To address this problem, proposed here is a novel VIV mitigation strategy for a long-span bridge: in the design stage, aerodynamic design involving VIV of the girder is conducted based on the normal structural damping suggested by the design code, and flexible membranes (FMs) are designed for emergency VIV mitigation of the girder in case of very low structural damping after completion; if the girder experience large-amplitude VIV after completion because of very low structural damping, then the pre-designed FMs are used as a temporary emergency aerodynamic measure for fast VIV mitigation, providing a transition period until permanent measures (such as mechanical dampers, or aerodynamic measures) are implemented. To investigate the feasibility of this strategy, a case study was conducted involving a series of wind tunnel tests on a cable-stayed bridge with a Π-shaped girder, and the results indicate that appropriate FMs are effective for suppressing the VIV of the girder under very low structural damping. The FMs have great potential for emergency VIV mitigation because of the low cost, convenience, and rapidity.

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Flapping dynamics of a flexible membrane attached to the leading edge of a forward-facing step

Cited by 2 publications

References 47 publications

Numerical simulation study on the effect of porosity on the flapping characteristics of perforated flags in different flow environments

Numerical simulation study on the effect of porosity on the flapping characteristics of perforated flags in different flow environments

A novel strategy for mitigating the vortex-induced vibration of long-span bridges by using flexible membranes

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