Low-frequency underwater sound generation by impacting transient cylindrical water jets

Kolaini, Ali R.; Roy, Ronald A.; Crum, Lawrence A.; Mao, Yi

doi:10.1121/1.407373

Cited by 17 publications

(15 citation statements)

References 12 publications

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“…3 where multiple density lines exist inside the bubble and at the air-liquid surface. This matches the observation obtained from cinematography in the experiment of Kolaini et al, 12 which suggested that the "bubble plume" could be a large air-filled bubble with a roughened surface that contains air-water mixture.…”

Section: A Near-field Resultssupporting

confidence: 85%

“…Water surrounding the neck rushes radially toward the axis of symmetry, pinching off a large bubble plume. Detailed photographic images can be found in Kolaini et al 12 and ͑Szymczak et al͒. 31 The de- tached bubble plume undergoes volume pulsations, constituting a strong acoustic source radiating low-frequency sound.…”

Section: A Near-field Resultsmentioning

confidence: 99%

“…It has been recognized by many researchers that the forcing mechanism for bubble oscillations is air entrainment and bubble fission. 3,12 On the theoretical side, Oguz 13 proposed an effective pressure model by considering a distribution of bubbles at the airwater interface. Based on Oguz's model and experimental observation showing that it is the newly entrained bubbles at the leading edge of the breaker that are the primary source of sound from breaking waves, 3,14 Means and Heitmeyer 15 developed a more physically realistic bubble cloud excitation model by treating newly formed bubbles as point sources.…”

Section: Introductionmentioning

confidence: 99%

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Coupled hydrodynamic-acoustic modeling of sound generated by impacting cylindrical water jets

Means

Szymczak

Rogers³

2008

The Journal of the Acoustical Society of America

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A coupled hydrodynamic-acoustic model describing acoustic propagation in a fluid containing multiple bubbles is proposed and applied to simulate noise generated by impacting water jets. The total pressure is decomposed into a "hydrodynamic" part and an "acoustic" part and computed using different schemes. The hydrodynamic pressure field is calculated independently using a generalized hydrodynamic model, and the pressure variations serve as sources in the wave equation for the acoustic pressure. A numerical algorithm developed to calculate wave propagation in an irregular region is used to account for the existence of the cavities. Noise generated by the impact of two cylindrical water jets is predicted. The computed near-field pressure is compared with the experimental data.

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Section: A Near-field Resultssupporting

confidence: 85%

Section: A Near-field Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Coupled hydrodynamic-acoustic modeling of sound generated by impacting cylindrical water jets

Means

Szymczak

Rogers³

2008

The Journal of the Acoustical Society of America

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“…Another example is the impact of a continuous water mass, thus a liquid column or a jet, onto a pool (Kolaini et al 1993;Oguz, Prosperetti & Kolaini 1995;Clanet & Lasheras 1997;Storr & Behnia 1999;Kersten, Ohl & Prosperetti 2003;Szymczak, Means & Rogers 2004;Qu et al 2011). These studies focused on the bubbles resulting from the hydrostatic collapse of the generated cavity.…”

mentioning

confidence: 99%

Impact of a high-speed train of microdrops on a liquid pool

et al. 2016

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A train of high-speed microdrops impacting on a liquid pool can create a very deep and narrow cavity, reaching depths more than 1000 times the size of the individual drops. The impact of such a droplet train is studied numerically using boundary integral simulations. In these simulations, we solve the potential flow in the pool and in the impacting drops, taking into account the influence of liquid inertia, gravity and surface tension. We show that for microdrops the cavity shape and maximum depth primarily depend on the balance of inertia and surface tension and discuss how these are influenced by the spacing between the drops in the train. Finally, we derive simple scaling laws for the cavity depth and width.

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“…Kolaini, Roy & Crum (1991) and Kolaini et al (1993) have experimentally considered the problem of a stationary short-duration water jet impacting on a quiescent pool of water. In these experiments, a vertically oriented tube of water was held in place above the pool, which was subsequently released by the sudden rupture of a rubber membrane, allowing a cylinder of water to impact with the pool.…”

Section: Introductionmentioning

confidence: 99%

The impact of a translating plunging jet on a pool of the same liquid

2011

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An experimental study on the impact of a translating two-dimensional transient jet on an initially quiescent liquid pool is studied experimentally using high-speed cinematic visualization and particle image velocimetry methods. Six jet conditions (covering a range of jet thicknesses, velocities and inclination angles relative to vertical) are considered, with measurements performed over a range of horizontal translation speeds for each jet condition. For all conditions studied herein, the jet penetrates into the pool and forms two craters -one upstream and one downstream of the jet. Gravity acts to close these craters, which after a short time pinch off at intermediate depths, thereby entrapping cavities of air. The translation speed of the jet is found to have a dramatic effect on the cavity shapes, pinch-off depths and pinch-off times. A simple theory based on a potential flow and a hydrostatically driven collapse is used to model this flow, and the resulting jet tip trajectories and cavity shapes compare favourably with the experimental data.

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Low-frequency underwater sound generation by impacting transient cylindrical water jets

Cited by 17 publications

References 12 publications

Coupled hydrodynamic-acoustic modeling of sound generated by impacting cylindrical water jets

Coupled hydrodynamic-acoustic modeling of sound generated by impacting cylindrical water jets

Impact of a high-speed train of microdrops on a liquid pool

The impact of a translating plunging jet on a pool of the same liquid

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