Byeong Rog Shin scite author profile

Byeong Rog Shin

5Publications

124Citation Statements Received

66Citation Statements Given

How they've been cited

228

120

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Affiliations

Changwon National University, Tohoku University

Publications

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Numerical Study of Sheet Cavitation Breakoff Phenomenon on a Cascade Hydrofoil

Iga

Nohmi

Gotō

et al. 2003

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Abstract2-D unsteady cavity flows through hydrofoils in cascade which is the most fundamental element of turbomachinery are numerically calculated. In particular, attention was paid to instability phenomena of the sheet cavity in transient cavitation condition and the mechanism of break-off phenomenon was examined. A TVD MacCormack's scheme employing a locally homogeneous model of compressible gas-liquid two-phase media was applied to analyze above cavity flows. The present method permits us to treat the whole cavitating/noncavitating unsteady flow field. By analyzing numerical results in detail, it became clear that there are at least two mechanisms in the break-off phenomena of sheet cavity; one is that re-entrant jets play a dominant role in such a break-off phenomenon, and the other is that pressure waves propagating inside the cavity bring about an another type of break-off phenomenon accompanied with cavity surface waves.

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Numerical simulation of unsteady cavitating flows using a homogenous equilibrium model

Shin

Iwata

Ikohagi

2003

Computational Mechanics

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Numerical simulations of two-dimensional cavity flows around a flat plate normal to flow and flows through a 90 bent duct are performed to clarify unsteady behavior under various cavitation conditions. A numerical method applying a TVD-MacCormack scheme with a cavitation model based on a homogenous equilibrium model of compressible gas-liquid two-phase media proposed by the present authors, is applied to solve the cavitating flow. This method permits the simple treatment of the whole gas-liquid two-phase flow field including wave propagation and large interface deformation. Numerical results including detailed observations of unsteady cavity flows and comparisons of predicted results with experimental data are provided. IntroductionIt has become highly desirable in recent years for highspeed hydraulic machinery and equipment to provide reliable operation over a wide range of operating conditions and with improved performance. In the estimation of performance, the existence of unsteady cavity flow, which is considered to be a high-speed gas-liquid two-phase flow accompanied by cavitation, is a very important factor (Brennen 1994). Numerous attempts have been made to clarify the behavior of cavity flow using a range of gas-liquid two-phase flow models for numerical simulations, including Kubota et al. In these previous investigations, however, there has been no comprehensive application to the transient flow range from the subcavitation state to the supercavitation state. Okuda and Ikohagi (1996) contrived a cavitation model based on a homogenous equilibrium model taking account of the compressibility of the gas-liquid two-phase medium. A numerical method incorporating this model and MacCormack's predictor-corrector method (MacCormack 1982) has been proposed by the present authors (Okuda and Ikohagi 1996; Shin and Ikohagi 1997). The feature of this method is that the numerical simulation for an entire cavity flow field can be performed simply in a fixed mesh system without the need to capture the gas-liquid interface (e.g., Delannoy and Kueny 1990; Chen and Heister 1994) or perform a remeshing procedure. In addition, interfaces including a large change of density can be treated as a contact discontinuity from the viewpoint of a compressible fluid.The purpose of this paper is to verify the applicability of the authors' method to a wide range of cavity flow and to clarify the unsteady behavior of some kinds of cavitation.As numerical examples, external and internal two-dimensional (2-D) cavity flows around a flat plate orientated normal to flow, and flows through a 90 bent duct are simulated. Detailed cavity flow behavior including the cavity length and width, and the drag and pressure distributions for the above flow fields are investigated and compared with available experimental data. Equation of stateLet us consider a local volumetric element in a gas-liquid two-phase flow field containing an arbitrary void fraction (gas volume fraction) a as shown in Fig. 1a. This element is assumed to be a mathematically homoge...

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Prediction of cavitating flow noise by direct numerical simulation

Seo

Moon

Shin

2008

Journal of Computational Physics

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A numerical method for natural convection and heat conduction around and in a horizontal circular pipe

Yamamoto

Niiyama

Shin

2004

International Journal of Heat and Mass Transfer

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An effective shape of floor splitter for reducing sub-surface vortices in pump sump

2014

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Byeong Rog Shin

Numerical Study of Sheet Cavitation Breakoff Phenomenon on a Cascade Hydrofoil

Numerical simulation of unsteady cavitating flows using a homogenous equilibrium model

Prediction of cavitating flow noise by direct numerical simulation

A numerical method for natural convection and heat conduction around and in a horizontal circular pipe

An effective shape of floor splitter for reducing sub-surface vortices in pump sump

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