AI Article Synopsis
- The study examines how bubble clouds react to pressure changes near a rigid wall using a new two-phase flow model.
- Key factors affecting bubble behavior include pressure amplitude and frequency, bubble size, void fraction, and distance from the wall, revealing that higher pressure amplitudes lead to stronger bubble interactions and greater pressure spikes on the wall.
- The findings indicate that the resonance frequency for maximum pressure load differs significantly from theoretical predictions, especially at high amplitudes where it decreases with increasing pressure ratios.
Article Abstract
The dynamics of a bubble cloud excited by a sinusoidal pressure field near a rigid wall is studied using a novel Eulerian/Lagrangian two-phase flow model. The effects of key parameters such as the amplitude and frequency of the excitation pressure, the cloud and bubble sizes, the void fraction, and the initial standoff distance on the bubbles' collective behavior and the resulting pressure loads on the nearby wall are investigated. The study shows that nonlinear bubble cloud dynamics becomes more pronounced and results in higher pressure loading at the wall as the excitation pressure amplitude increases. The strongest collective bubble behavior occurs at a preferred resonance frequency. At this resonance frequency, pressure peaks orders of magnitudes higher than the excitation pressure result from the bubble interaction when the amplitude of the pressure excitation is high. The numerically obtained resonance frequency is significantly different from the reported natural frequency of a spherical cloud derived from linear theory, which assumes small amplitude oscillations in an unbounded medium. At high amplitudes of the excitation, the resonance frequency decreases almost linearly with the ratio of excitation pressure amplitude to ambient pressure until the ratio is larger than one.
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| http://dx.doi.org/10.1016/j.ultsonch.2017.08.033 | DOI Listing |
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