Analysis of sheet cavitating flow structures by numerical and experimental studies

Bo Zhang; Guo Yu Wang; Xiang Bin Li; Zhan Zhong Han

Analysis of sheet cavitating flow structures by numerical and experimental studies

Bo Zhang^*, Guo Yu Wang, Xiang Bin Li, Zhan Zhong Han

^*Corresponding author for this work

School of Mechanical Engineering

Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

The structure of sheet cavitating flow around a hydrofoil was investigated by coupled experimental and numerical methods. A high-speed camera was used to visualize the flow structures, and Laser Doppler Velocity (LDV) was employed for velocity measurement. The results demonstrate that the sheet cavity is typically thin and has a series of sharp thin "fingers". As the cavitation number is reduced the cavitating region grows and becomes increasingly unstable, companying with the shedding of small cavitating vortices. Basically, the predicted cavitation phenomena coincide with those observed in the experiment for a hydrofoil. It indicates that the flowing model and computing method are reliable.

Original language	English
Pages (from-to)	1847-1851
Number of pages	5
Journal	Kung Cheng Je Wu Li Hsueh Pao/Journal of Engineering Thermophysics
Volume	29
Issue number	11
Publication status	Published - Nov 2008

Keywords

Flow structure
Numerical simulation
Sheet cavitation

Cite this

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title = "Analysis of sheet cavitating flow structures by numerical and experimental studies",

abstract = "The structure of sheet cavitating flow around a hydrofoil was investigated by coupled experimental and numerical methods. A high-speed camera was used to visualize the flow structures, and Laser Doppler Velocity (LDV) was employed for velocity measurement. The results demonstrate that the sheet cavity is typically thin and has a series of sharp thin {"}fingers{"}. As the cavitation number is reduced the cavitating region grows and becomes increasingly unstable, companying with the shedding of small cavitating vortices. Basically, the predicted cavitation phenomena coincide with those observed in the experiment for a hydrofoil. It indicates that the flowing model and computing method are reliable.",

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AU - Zhang, Bo

AU - Wang, Guo Yu

AU - Li, Xiang Bin

AU - Han, Zhan Zhong

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N2 - The structure of sheet cavitating flow around a hydrofoil was investigated by coupled experimental and numerical methods. A high-speed camera was used to visualize the flow structures, and Laser Doppler Velocity (LDV) was employed for velocity measurement. The results demonstrate that the sheet cavity is typically thin and has a series of sharp thin "fingers". As the cavitation number is reduced the cavitating region grows and becomes increasingly unstable, companying with the shedding of small cavitating vortices. Basically, the predicted cavitation phenomena coincide with those observed in the experiment for a hydrofoil. It indicates that the flowing model and computing method are reliable.

AB - The structure of sheet cavitating flow around a hydrofoil was investigated by coupled experimental and numerical methods. A high-speed camera was used to visualize the flow structures, and Laser Doppler Velocity (LDV) was employed for velocity measurement. The results demonstrate that the sheet cavity is typically thin and has a series of sharp thin "fingers". As the cavitation number is reduced the cavitating region grows and becomes increasingly unstable, companying with the shedding of small cavitating vortices. Basically, the predicted cavitation phenomena coincide with those observed in the experiment for a hydrofoil. It indicates that the flowing model and computing method are reliable.

KW - Flow structure

KW - Numerical simulation

KW - Sheet cavitation

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M3 - Article

AN - SCOPUS:56049126019

SN - 0253-231X

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JO - Kung Cheng Je Wu Li Hsueh Pao/Journal of Engineering Thermophysics

JF - Kung Cheng Je Wu Li Hsueh Pao/Journal of Engineering Thermophysics

IS - 11

ER -

Analysis of sheet cavitating flow structures by numerical and experimental studies

Abstract

Keywords

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