Numerical study of cloud cavitation effects on hydrophobic hydrofoils

Abstract Cavitation generates a portion of cavities called a cavitation cloud, which performs a collective unsteady motion of repeating the process of growth and collapse. In particular, it is considered that a high-pressure shock wave propagates associated with the collapse. In order to understand such unsteady behaviors of the cavitation cloud, much effort has been made for the numerical analysis of internal flows of the cavitation cloud. However, it is not clear how such a cavitation cloud can be identified as a physical entity nor how its unsteady collective motion can be elucidated in the context of the multiphase fluid flow. In this study, we make a two-dimensional numerical analysis of the multiphase flow of the submerged bubbly water jet injecting into still water through a nozzle. To model the bubbly water jet, we employ the mixture model of liquids and gases, and we utilize the Smoothed Particle Hydrodynamics method for the numerical analysis of the unsteady flows in Lagrangian description. Finally, in order to clarify the unsteady behaviors of the cloud cavitation, we show how the cavitation cloud can be generated in the context of velocity fields in the multiphase flow and in particular, we clarify how twin vortices induced by the water jet play an essential role in the expansion and shrinkage of the cloud.

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Numerical study on growth and collapse of cloud cavitation in a focused ultrasound field

10.1121/2.0000907 ◽

2018 ◽

Author(s):

Kohei Okita

Keyword(s):

Focused Ultrasound ◽

Numerical Study ◽

Cloud Cavitation ◽

Ultrasound Field

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Numerical Study on the Vibration and Noise Characteristics of a Delft Twist11 Hydrofoil

Journal of Marine Science and Engineering ◽

10.3390/jmse9020144 ◽

2021 ◽

Vol 9 (2) ◽

pp. 144

Author(s):

Hong-Sik Hwang ◽

Kwang-Jun Paik ◽

Soon-Hyun Lee ◽

Gisu Song

Keyword(s):

Numerical Study ◽

Marine Ecosystem ◽

Pressure Fluctuations ◽

Liquid Lead ◽

Cloud Cavitation ◽

Cavitation Inception ◽

Radiated Noise ◽

Sheet Cavitation ◽

Noise Characteristics ◽

Noise Vibration

Underwater radiated noise (URN) is greatly increasing due to an increase in commercial shipping, sonar activities, and climate change. As a result, marine life is having difficulty communicating, and marine ecosystem disturbances are occurring. The noise from the cavitation of propellers is affecting URN. Cavitation is a phenomenon in which rapid changes of pressure in a liquid lead to the formation of small vapor-filled cavities in places where the pressure is relatively low. This phenomenon results in poor efficiency of the propeller or turbine of a ship and noise, vibration, and erosion. For these reasons, this study examines the URN of sheet and cloud cavitation. A numerical analysis was done using a Delft Twist11 hydrofoil. The URN resulting from cloud cavitation and sheet cavitation was compared with the numerical results of previous studies. The results showed that URN normally increases due to pressure fluctuations when cavitation occurs. URN increased more significantly in conditions of cloud cavitation than in cavitation inception. It is also shown that a frequency begins to occur after the occurrence of the cloud cavitation, and the frequency grew as the cavitation fully developed.

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Numerical Study on Flow-Induced Vibration Characteristics of Three-Dimensional Hydrofoil in Cavitating Flow

Volume 5: Multiphase Flow ◽

10.1115/ajkfluids2019-5153 ◽

2019 ◽

Author(s):

Chang Wang ◽

Yuan-qing Liu ◽

Te-zhuan Du ◽

Yi-wei Wang

Keyword(s):

Numerical Study ◽

Density Ratio ◽

Three Dimensional ◽

Simulation Method ◽

Cavitating Flow ◽

Vibration Characteristics ◽

Structural Vibration ◽

Cavitation Flow ◽

Flow Induced Vibration ◽

Cloud Cavitation

Abstract With the increasing demand of higher performance and efficiencies for marine propulsion and hydropower system, structures became more flexible and were subjected to high flow rates. Cavitation-structure interaction has become one of the major issues for most engineering applications. In order to analyze the characteristics of unsteady cavitating flow induced vibration, the cloud cavitation flow over three dimensional NACA66 hydrofoil is studied by numerical simulation in this paper. The cavitating flow is modeled by large eddy simulation method and Zwart cavitation model, and the structural vibration model of three dimensional hydrofoil is established. The numerical calculation of fluid-solid coupling is realized based on ANSYS Workbench. The main dimensionless parameters of three-dimensional hydrofoil cavitation flow-induced vibration are obtained by means of dimensional analysis, including density ratio, cavitation number, Reynolds number, and the frequency ratio of flow to structure. The changes of cavity morphology during the cloud cavitation development of flexible hydrofoil and the flow-induced vibration characteristics under cloud cavitation flow of flexible hydrofoil are analyzed. The results showed that the periodic development of cavitation can be divided into three stages: the growth of attached cavity, the development of re-entrant jet and the shedding of cavity in cloud cavitaion stage. The centroid displacement of the free end of the flexible hydrofoil varies periodically with time at the stage of cloud cavitation. The hydrofoil vibration is affected by the development of cloud cavitation, and the vibration frequency corresponds to the shedding frequency of cloud cavitation.

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