Your search keyword '"Jeong, Kwang-Leol"' showing total 2 results

1. A numerical simulation method for free surface flows near a two-dimensional moving body in fixed rectangular grid system

Author

Lee, Young-Gill, Jeong, Kwang-Leol, and Kim, NamChul

Subjects

*COMPUTER simulation, *TWO-dimensional models, *GRID computing, *FLUID dynamics, *NONLINEAR theories, *NAVIER-Stokes equations, *OSCILLATIONS

Abstract

Abstract: A numerical simulation method is developed for the description of a two-dimensional body moving in free surface flows using a fixed rectangular grid system. The nonlinear free surface is determined by the modified Marker-density method. The body boundary is defined by the line segments connecting the points where the body surface and grid lines meet. The Navier–Stokes equations and the continuity equation are used as the governing equations, which are coupled with a two-step projection method described in detail in this research. The velocities and pressures in the body boundary cells as well as the free surface cells are calculated using a simultaneous iterative method. For the verification of the present numerical method, four kinds of simulations have been conducted. The first case is to investigate the vortex shedding of an advancing cylinder, the second case is about the forced oscillation of a box, the third case is to clarify the sloshing phenomenon in a horizontally excited tank, and the last case is waves generation by a plunging-type wave maker. The simulation results are confirmed with corresponding experimental results or analytical solutions. [Copyright &y& Elsevier]

Published

2013

2. The Marker-density method in cartesian grids applied to nonlinear ship waves

Author

Lee, Young-Gill, Jeong, Kwang-Leol, and Kim, NamChul

Subjects

*SHIP models, *FLUID dynamics, *NONLINEAR systems, *GRID computing, *COMPUTER simulation, *ITERATIVE methods (Mathematics), *NAVIER-Stokes equations

Abstract

Abstract: A numerical simulation method is presented for nonlinear waves generated by advancing ships. The nonlinear free surface is determined by a modified Marker-density method. Pressures and velocities in body boundary cells and free surface cells are calculated through a simultaneous iterative method. The filtered Navier–Stokes equations and filtered continuity equation are used as governing equations. The equations are solved by using a finite difference method in a Cartesian grid system. The body boundary is defined by the line segments connecting the points where grid lines and body surface meet. Pressures are coupled with velocities through two-step projection method in the present approach. The governing equations are approximated in finite difference form using a forward time centered space (FTCS) scheme except convection terms. The convection terms are approximated in finite difference form employing third order upwind scheme in space and Adams–Bashforth scheme in time. For the verification of the present numerical simulation, a numerical computation is carried out with Series-60 cargo ship. For the grid convergence test, three grid levels are selected with a constant grid refinement ratio. For the purpose of understanding spilling type breaking waves near a ship bow, a wedge shape model is selected, and its numerical simulation is performed using the computational fluid dynamics program developed during the present research. For a specific case, plunging type breaking bow waves with scars which are frequently generated by a planing hull type patrol ship, are numerically simulated at several different speeds. In addition, the pressure resistance coefficients from the numerical computations are investigated in detail with respect to the residual resistance coefficients from the corresponding ship model experiments. [Copyright &y& Elsevier]

Published

2012