Dynamic characterization of a singlenear-wall cavitation bubble collapses in ahigh-hydraulic water body

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Journal of Vibration and Shock ›› 2023, Vol. 42 ›› Issue (11) : 11-18.

LIAO Bin， YANG Zaihe， BU Yang， CHEN Shanqun

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Abstract

Based on 6-equation multiphase flow simulation theory and combined with the comparative validation of semi-analytic solution of Keller-Miksis equation, a numerical model which is used to study the near-wall cavitation bubble collapse problem in a high-hydraulic pressure water body is established. Three high-hydraulic pressure conditions, p∞ = 106Pa, p∞ = 107Pa and p∞ = 108Pa, and four cavitation bubble-wall spacing conditions, S = 0.1R0, S = 0.4R0, S = 0.7R0 and S = 1.1R0, were selected to systematically investigate the dynamic characteristics of a single near-wall cavitation bubble collapses in a high-hydraulic pressure water body. Combined with the post-processing techniques, such as numerical schlieren and pressure field dimensionless, the collapse evolution of the cavitation bubble, the generation and propagation of the pressure waves, and the pressure peak at the radial origin of the wall under different working conditions were compared and analyzed in detail. The influence of the hydraulic pressure of the surrounding water and the spacing between the cavitation bubble and the wall on the collapse dynamics of the near-wall cavitation bubble was elaborated, and the internal mechanisms contained was also revealed.

Key words

cavitation bubble / collapse / high-hydraulic pressure / spacing / pressure wave

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LIAO Bin， YANG Zaihe， BU Yang， CHEN Shanqun. Dynamic characterization of a singlenear-wall cavitation bubble collapses in ahigh-hydraulic water body[J]. Journal of Vibration and Shock, 2023, 42(11): 11-18

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