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Original scientific paper

NUMERICAL AND EXPERIMENTAL STUDY OF TURBULENT FREE SURFACE FLOW FOR A FAST SHIP MODEL

Yavuz Hakan Ozdemir ; Faculty of Naval Arch. and Maritime, Yildiz Tech. Univ, Istanbul, Turkey
Baris Barlas orcid id orcid.org/0000-0002-5846-2369 ; Faculty of Naval Arch. and Ocean Engin., Istanbul Tech. Univ., Istanbul, Turkey
Tamer Yilmaz ; Faculty of Naval Arch. and Maritime, Yildiz Tech. Univ, Istanbul, Turkey
Seyfettin Bayraktar ; Faculty of Naval Arch. and Maritime, Yildiz Tech. Univ, Istanbul, Turkey


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Abstract

In this study the experimental and computational results for a fast ship model is presented. The Reynolds Averaged Navier Stokes (RANS) equations and the nonlinear free surface boundary conditions are discretized by means of an overset grid finite volume scheme. The experiments are performed at Istanbul Technical University Towing Tank basin. In the numerical turbulent flow calculations, the relationship between the Boussinesq's hypothesis of turbulence viscosity and the velocities are obtained through the standard k-ε turbulence model. Simulations of turbulent free surface flows around the model are performed by using Star CCM+ solver and Volume of Fluid (VOF) model to capture the free surface between air and water. The total resistance of the ship model is compared with the experimental results. Bow and aft wave form developments are also investigated qualitatively. For Froude (Fn) numbers less than 0.25, the computations are found to be well satisfactory, giving efficient and accurate tool to predict curves of resistance. For relatively higher speeds (Fn>0.25) a low Reynolds number turbulence model may be more suitable to predict the resistance.

Keywords

CFD; Turbulent free surface flows; Star CCM+; fast hull; k-ε turbulence model

Hrčak ID:

118040

URI

https://hrcak.srce.hr/118040

Publication date:

25.3.2014.

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