Evaluation of turbulence models for the numerical simulation of supercavitating flows around a hydrofoil

Xiang Bin Li; Guo Yu Wang; Bo Zhang; Zhi Yi Yu

Evaluation of turbulence models for the numerical simulation of supercavitating flows around a hydrofoil

Xiang Bin Li^*, Guo Yu Wang, Bo Zhang, Zhi Yi Yu

^*Corresponding author for this work

School of Mechanical Engineering

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

5 Citations (Scopus)

Abstract

Supercavitating flows around a hydrofoil is simulated to grasp the unsteady behaviour numerically. To evaluate the application of turbulence models in the computations of supercavitating flows, three different models are implemented: Standard κ ε model, RNG κ ε model and SSG Reynolds stress model. And then, numerical results were compared to experimental ones. The results showed that the standard κ ε model can only simulate the steady supercavitating behavior. However, both the RNG κ ε model and SSG Reynolds stress model can obtain two-phase mixture characteristics in the cavity area, especially the reverse fluctuating processes of the interface between the vapor phase and water-vapor mixture phase. It is also noted that the maximum cavity length simulated by the RNG κ ε model agrees well with the experimental one.

Original language	English
Pages (from-to)	975-978
Number of pages	4
Journal	Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology
Volume	28
Issue number	11
Publication status	Published - Nov 2008

Keywords

Supercavitation
Turbulence model
Unsteady characteristics

Cite this

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title = "Evaluation of turbulence models for the numerical simulation of supercavitating flows around a hydrofoil",

abstract = "Supercavitating flows around a hydrofoil is simulated to grasp the unsteady behaviour numerically. To evaluate the application of turbulence models in the computations of supercavitating flows, three different models are implemented: Standard κ ε model, RNG κ ε model and SSG Reynolds stress model. And then, numerical results were compared to experimental ones. The results showed that the standard κ ε model can only simulate the steady supercavitating behavior. However, both the RNG κ ε model and SSG Reynolds stress model can obtain two-phase mixture characteristics in the cavity area, especially the reverse fluctuating processes of the interface between the vapor phase and water-vapor mixture phase. It is also noted that the maximum cavity length simulated by the RNG κ ε model agrees well with the experimental one.",

keywords = "Supercavitation, Turbulence model, Unsteady characteristics",

author = "Li, {Xiang Bin} and Wang, {Guo Yu} and Bo Zhang and Yu, {Zhi Yi}",

year = "2008",

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T1 - Evaluation of turbulence models for the numerical simulation of supercavitating flows around a hydrofoil

AU - Li, Xiang Bin

AU - Wang, Guo Yu

AU - Zhang, Bo

AU - Yu, Zhi Yi

PY - 2008/11

Y1 - 2008/11

N2 - Supercavitating flows around a hydrofoil is simulated to grasp the unsteady behaviour numerically. To evaluate the application of turbulence models in the computations of supercavitating flows, three different models are implemented: Standard κ ε model, RNG κ ε model and SSG Reynolds stress model. And then, numerical results were compared to experimental ones. The results showed that the standard κ ε model can only simulate the steady supercavitating behavior. However, both the RNG κ ε model and SSG Reynolds stress model can obtain two-phase mixture characteristics in the cavity area, especially the reverse fluctuating processes of the interface between the vapor phase and water-vapor mixture phase. It is also noted that the maximum cavity length simulated by the RNG κ ε model agrees well with the experimental one.

AB - Supercavitating flows around a hydrofoil is simulated to grasp the unsteady behaviour numerically. To evaluate the application of turbulence models in the computations of supercavitating flows, three different models are implemented: Standard κ ε model, RNG κ ε model and SSG Reynolds stress model. And then, numerical results were compared to experimental ones. The results showed that the standard κ ε model can only simulate the steady supercavitating behavior. However, both the RNG κ ε model and SSG Reynolds stress model can obtain two-phase mixture characteristics in the cavity area, especially the reverse fluctuating processes of the interface between the vapor phase and water-vapor mixture phase. It is also noted that the maximum cavity length simulated by the RNG κ ε model agrees well with the experimental one.

KW - Supercavitation

KW - Turbulence model

KW - Unsteady characteristics

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JF - Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology

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ER -

Evaluation of turbulence models for the numerical simulation of supercavitating flows around a hydrofoil

Abstract

Keywords

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