«Previous Article|Table of Contents|Next Article»

Journal of Marine Science and Application[ISSN:1002-2848/CN:61-1400/f]

卷:

期数:

2010年2

页码:

109-114

栏目:

出版日期:

2010-06-25

Info

Title:

Numerical Simulation and Experiment on Dam Break Problem

Author(s):

Changhong Hu*and Makoto Sueyoshi

Affilations:

Author(s):

Changhong Hu*and Makoto Sueyoshi

Research Institute for Applied Mechanics, Kyushu University，
Kasuga Fukuoka 816-8580, Japan

Keywords:

CIP method;  MPS method;  dam break experiment

分类号:

-

DOI:

-

Abstract:

In this paper, two novel numerical computation methods are introduced which have been recently developed at Research Institute for Applied Mechanics ( RIAM ), Kyushu University, for strongly nonlinear wave-body interaction problems, such as ship motions in rough seas and resulting green-water impact on deck. The first method is the CIP-based Cartesian grid method, in which the free surface flow is treated as a multi-phase flow which is solved using a Cartesian grid. The second method is the MPS method, which is a so-called particle method and hence no grid is used. The features and calculation procedures of these numerical methods are described. One validation computation against a newly conducted experiment on a dam break problem, which is also described in this paper, is presented.

References:

Hirt CW, Nichols BD (1981). Volume of fluid (VOF) methods for the dynamic of free boundaries. Comput. Phys， 39， 201-225.
Hu C, Kashiwagi M (2004), A CIP-Based method for numerical simulations of violent free surface flows. Marine Science and Technology, 9(4), 143-157.
Hu C, Kashiwagi M (2006a). Validation of CIP-Based method for strongly nonlinear wave-body interactions. Proc. 26th Symposium on Naval Hydrodynamics, Rome, 4, 247-258. Hu C, Kishev Z, Kashiwagi M, Sueyoshi M, Faltinsen OM (2006b). Application of CIP method for sStrongly nonlinear marine hydrodynamics. Ship Technology Research, 53( 2), 74-87.
 Hu C, Kashiwagi M (2007). Numerical and experimental studies on three-dimensional water on deck with a modified wigley model. Proc. 9th Numerical Ship Hydrodynamics, Ann Arbor, Michigan, 1, 159-169.
 Hu C, Kashiwagi M, Sueyoshi M (2008). Improvement towards high-resolution computation on strongly nonlinear wave-induced motions of an actual ship. Proc. of 27th Symposium on Naval Hydrodynamics, Soeul, Korea, 5-10, 525-534.
 Hu C, Kashiwagi M (2009). Two-dimensional numerical simulation and experiment on strongly nonlinear wave–body interactions. Marine Science and Technology, 9, 143-157
Kishev Z, Hu C, Kashiwagi M (2006). Numerical simulation of violent sloshing by a CIP-Based method. Marine Science and Technology, 11, (2), 111-122. Koshizuka S, Oka Y (1996). Moving-Particle Semi-Implicit method for fragmentation of incompressible fluid. Nuclear Science and Engineering, 123, 421-434.
 Martin JC, Moyce WJ (1952). An experimental study of collapse of liquid columns on a rigid horizontal plane. Philos. Trans. R. Soc.. London Ser. A, 244, 312-324. Sueyoshi M, Naito S (2003). A numerical study of violent free surface problems with particle method for marine engineering. Proc.8th Numerical Ship Hydrodynamics, Busan, 2, 330-339.
 Sueyoshi M, Naito S (2004). A 3-D simulation of nonlinear fluid problem by particle method – Over One Million Particles Parallel Computing on PC Cluster –. Kansai Soc. Nav. Arch,. Japan, 241, 133-142.
 Sueyoshi M, Kashiwagi M, Naito S (2008). Numerical simulation of wave-induced nonlinear motions of a two-dimensional floating body by the moving particle semi-implicit method. Marine Science and Technology, 13, 85-94.
 Xiao F, Honma Y, Kono T (2005). A simple algebraic interface capturing scheme using hyperbolic tangent function. Int. J. Numerical Methods in Fluids, 48, 1023-1040.
Yabe Y, Xiao F, Utsumi T (2001). The constrained interpolation profile method for multiphase analysis. Comp Physics, 169, 556-569.

Memo

Memo:

-

Commonly used function

Last Update: 2010-06-01