Experiments on non-resonant sloshing in a rectangular tank with large amplitude lateral oscillation

Experiments on non-resonant sloshing in a rectangular tank with large amplitude lateral oscillation

Flow of two dimensional nonlinear sloshing in a rigid rectangular tank with free surface is considered. The flow is generated by oscillating the container in a lateral harmonic motion, i.e., d⁎=A⁎sin(2πf⁎t⁎) where d⁎ denotes the displacement of the container externally forced, A* the amplitude of di...

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Veröffentlicht in:Ocean engineering 2012-08, Vol.50, p.10-22
Hauptverfasser: Moo Ji, Young, Sup Shin, Young, Sang Park, Jun, Min Hyun, Jae
Format: Artikel
Sprache:eng
Schlagworte:
Amplitudes
Applied sciences
Buildings. Public works
Computation methods. Tables. Charts
Containers
Displacement
Exact sciences and technology
Harmonic oscillation
Hydraulic constructions
Hydraulic jump
Marine
Movement
Natural frequency
Nonlinear sloshing
Nonlinearity
Run up
Standing wave
Strokes
Structural analysis. Stresses
Tanks
Wave propagation
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creator Moo Ji, Young
Sup Shin, Young
Sang Park, Jun
Min Hyun, Jae
description Flow of two dimensional nonlinear sloshing in a rigid rectangular tank with free surface is considered. The flow is generated by oscillating the container in a lateral harmonic motion, i.e., d⁎=A⁎sin(2πf⁎t⁎) where d⁎ denotes the displacement of the container externally forced, A* the amplitude of displacement and f* the frequency. Thus, the maximum stroke, S*, of the container for a cycle, measured by a distance from the leftmost to the rightmost location on the container movement, is defined as S*=2A*. It has performed a sequence of experiments on a variety of S*- and f*-values to investigate large amplitude sloshing flows at off-resonant condition far from the system natural frequency, where large amplitude means that the stroke, S*, of the container movement is comparable with the breadth, L*, of the container, i.e., S*/L*∼O(1) and the excitation acceleration is also comparable with the gravity, i.e., π2(S*f*)2/g*∼O(1). Through PIV experiment, it shows that the flow physics on nonlinear off-resonant sloshing problem can be characterized into a combination of three peculiar sloshing motions: (1) standing wave motions which is similar with those of linear sloshing during run-down process, (2) run-up phenomenon like hydraulic jump along the vertical sidewall at the moment of turn-around of the container and (3) gradually propagating bore motion from one sidewall to the opposite wall which is similar with dam breaking problem. ► A flow of two dimensional nonlinear sloshing in a rigid rectangular tank is considered. ► The flow is generated by oscillating the container in a lateral harmonic motion. ► The flow physics could be characterized into three peculiar sloshing motions. ► Hydraulic jump like bore motion is possible at the early stage of run-up process.
doi_str_mv 10.1016/j.oceaneng.2012.04.007
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The flow is generated by oscillating the container in a lateral harmonic motion, i.e., d⁎=A⁎sin(2πf⁎t⁎) where d⁎ denotes the displacement of the container externally forced, A* the amplitude of displacement and f* the frequency. Thus, the maximum stroke, S*, of the container for a cycle, measured by a distance from the leftmost to the rightmost location on the container movement, is defined as S*=2A*. It has performed a sequence of experiments on a variety of S*- and f*-values to investigate large amplitude sloshing flows at off-resonant condition far from the system natural frequency, where large amplitude means that the stroke, S*, of the container movement is comparable with the breadth, L*, of the container, i.e., S*/L*∼O(1) and the excitation acceleration is also comparable with the gravity, i.e., π2(S*f*)2/g*∼O(1). 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Tables. Charts</subject><subject>Containers</subject><subject>Displacement</subject><subject>Exact sciences and technology</subject><subject>Harmonic oscillation</subject><subject>Hydraulic constructions</subject><subject>Hydraulic jump</subject><subject>Marine</subject><subject>Movement</subject><subject>Natural frequency</subject><subject>Nonlinear sloshing</subject><subject>Nonlinearity</subject><subject>Run up</subject><subject>Standing wave</subject><subject>Strokes</subject><subject>Structural analysis. 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Public works</topic><topic>Computation methods. Tables. Charts</topic><topic>Containers</topic><topic>Displacement</topic><topic>Exact sciences and technology</topic><topic>Harmonic oscillation</topic><topic>Hydraulic constructions</topic><topic>Hydraulic jump</topic><topic>Marine</topic><topic>Movement</topic><topic>Natural frequency</topic><topic>Nonlinear sloshing</topic><topic>Nonlinearity</topic><topic>Run up</topic><topic>Standing wave</topic><topic>Strokes</topic><topic>Structural analysis. 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source ScienceDirect Journals (5 years ago - present)
subjects Amplitudes
Applied sciences
Buildings. Public works
Computation methods. Tables. Charts
Containers
Displacement
Exact sciences and technology
Harmonic oscillation
Hydraulic constructions
Hydraulic jump
Marine
Movement
Natural frequency
Nonlinear sloshing
Nonlinearity
Run up
Standing wave
Strokes
Structural analysis. Stresses
Tanks
Wave propagation
title Experiments on non-resonant sloshing in a rectangular tank with large amplitude lateral oscillation
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