Characterization as measurement sound source of acoustic cavitation noise from bubble clusters under ultrasonic horn

Kuroyama, Takanobu; Ogasawara, Hiroshi; Mori, Koichi

doi:10.35848/1347-4065/acb8a5

Cited by 6 publications

(6 citation statements)

References 34 publications

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“…The schlieren visualization system was the same as in the previous study. 34) Image capture was triggered at 8.8 μs after the hydrophone output exceeded the threshold level. a dagger in Fig.…”

Section: Distribution Of Acoustic Cavitation Noise Originmentioning

confidence: 99%

“…As a result, we confirmed that acoustic cavitation noise has steep autocorrelation characteristics with short main lobe full width at half maximum (FWHM) of 87 ns and low side lobe level. 34) Next, we developed an echo sounder employing acoustic cavitation noise, 35,36) and the experiments with a small water tank showed that the echo sounder could successfully measure the target range and spectral sound pressure reflection coefficient in a frequency range between 100 kHz and 5 MHz. However, this experiment highlighted the problem that the acoustic cavitation noise generated by the horn had low spatial coherence.…”

Section: Introductionmentioning

confidence: 99%

“…Geometric analysis in the previous study revealed that the larger the distribution width of acoustic cavitation bubble clusters and the angle Δf degrade the correlation more. 36) However, the relationship has not been provided quantitatively, considering the frequency characteristics of acoustic cavitation noise.…”

Section: Introductionmentioning

confidence: 99%

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Theoretical analysis and experimental verification of spatial coherence of acoustic cavitation noise from bubble clusters under ultrasonic horn

Kuroyama,

Ogasawara,

Mori

2024

Jpn. J. Appl. Phys.

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Acoustic cavitation bubbles under ultrasonic horn in water emit acoustic cavitation noise, which consists of spherical shockwaves. This study theoretically derived the spatial coherence of acoustic cavitation noise or, more precisely, the spectral degree of coherence. The acoustic cavitation noise was found to have spatial coherence characteristics similar to the "thermal light" in optics, unlike ultrasound generated by general transducers, which are analogous to "laser" with high coherence. The experiments validated the derived theory and showed that the spectral degree of coherence of the acoustic cavitation noise depends on the product between the distribution width of the shockwave origin, proportional to the horn diameter, and the angle between the hydrophones viewed from the horn. The lower the product gives, the higher the spectral degree of coherence at a higher frequency range.

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Section: Distribution Of Acoustic Cavitation Noise Originmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Theoretical analysis and experimental verification of spatial coherence of acoustic cavitation noise from bubble clusters under ultrasonic horn

Kuroyama,

Ogasawara,

Mori

2024

Jpn. J. Appl. Phys.

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“…1) This phenomenon is termed ultrasonic cavitation. [2][3][4][5][6] Because the collapse of bubbles by ultrasound is caused by semi-adiabatic compression, a high-temperature field is generated inside the bubbles, and a chemical reaction occurs. This reaction is termed a sonochemical reaction.…”

Section: Introductionmentioning

confidence: 99%

Dependence of reaction on vessel position, diameter, and liquid height in the sonochemical reactor with indirect irradiation

Yasuda,

Yamazaki,

Asakura

2024

Jpn. J. Appl. Phys.

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To investigate the sonochemical reaction performance caused by indirect irradiation at 500 kHz, the glass vessel and a KI aqueous solution were used. Both the ultrasonic power and reaction rate had maximum values at every half wavelength of ultrasound. When the vessel position was adjusted to a larger absolute value of transducer impedance, the reaction rate became higher. The reaction rate and ultrasonic power increased as the vessel position was closer to the transducer. The reaction rate first increased as the electric power applied to the transducer increased, reached a maximum value, and then decreased. This decrease phenomenon is called quenching of the sonochemical reaction. Before the quenching occurrence, the reaction rate per unit volume almost linearly increased with ultrasonic power density. The effects of the vessel diameter and liquid height on the relationship between the reaction rate per unit volume and the ultrasonic power density were small.

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“…It can gradually develop into a multiphase, multiscale state that includes small-scale cavity growth and collapse behavior, as well as large-scale cavitation evolution behavior. Meanwhile, cavitation typically results in vibration [1] , erosion [2] , and noise [3] , which can significantly impede the advancement of technology and equipment in high-speed hydrodynamic fields such as underwater weapons, underwater launch, aerospace, fluid machinery, and national defense. Therefore, accurately capturing the bubble structure at various scales and analyzing the transformation Based on high-speed water tunnels and high-speed camera technology, numerous experimental studies have shown that cavitation patterns gradually develop from incipient to sheet, cloud, and supercavitation as the Reynolds number increases or the cavitation number decreases.…”

Section: Introductionmentioning

confidence: 99%

Multi-scale characteristics investigation of sheet/cloud cavitation

Tian

et al. 2023

IOP Conf. Ser.: Mater. Sci. Eng.

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Sheet and cloud cavitation involve the formation of large-scale cavities and microbubbles across a wide range of length scales. In this study, a two-way coupling Eulerian-Lagrangian algorithm was utilized to simulate the cavitating flow around a NACA66 hydrofoil at an incidence of 8 degrees and a cavitation number of 1.2. The large eddy simulation (LES) and volume of fraction (VOF) methods are used to capture the large scale vapor structures in Eulerian frame. Meanwhile, the discrete bubble model (DBM) and simplified Rayleigh-Plesset equation are implied to solve the dynamic of Lagrangian microbubbles smaller than local grid scale. The results indicate that large-scale cavities are periodically shed downstream, influenced alternatively by the re-entrant jet and shock wave mechanisms, resulting in periodic variations of both the number and Sauter mean diameter of microscale bubbles. During the quasi-periodic evolution process of sheet/cloud cavitation, the microbubbles scatter around the large scale cavities where have strong turbulence intensity and high vorticity, and the probability density function of discrete bubble diameter similarly conforms to Gamma distribution with the dominant bubble size between 30 and 70μm. During the growth of an attached cavity, the number density of bubbles follows a power-law scaling with a value of -5/3 on radius. For the other stages, the bubble size spectrum of smaller microbubbles exhibits a -2/3 power-law scaling when the diameter of the microbubble is less than 200 μm. For larger bubbles with a diameter greater than 300 μm, the bubble density is proportional to the bubble radius to the power of -6.

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Characterization as measurement sound source of acoustic cavitation noise from bubble clusters under ultrasonic horn

Cited by 6 publications

References 34 publications

Theoretical analysis and experimental verification of spatial coherence of acoustic cavitation noise from bubble clusters under ultrasonic horn

Theoretical analysis and experimental verification of spatial coherence of acoustic cavitation noise from bubble clusters under ultrasonic horn

Dependence of reaction on vessel position, diameter, and liquid height in the sonochemical reactor with indirect irradiation

Multi-scale characteristics investigation of sheet/cloud cavitation

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