Citation:
Xing Zheng and Wen-yang Duan.Numerical Simulation of Dam Breaking Using Smoothed Particle Hydrodynamics and Viscosity Behavior[J].Journal of Marine Science and Application,2010,(1):34-41.
Click and Copy
Numerical Simulation of Dam Breaking Using Smoothed Particle Hydrodynamics and Viscosity Behavior
Xing Zheng and Wen-yang Duan.Numerical Simulation of Dam Breaking Using Smoothed Particle Hydrodynamics and Viscosity Behavior[J].Journal of Marine Science and Application,2010,(1):34-41.
Info
- Title:
- Numerical Simulation of Dam Breaking Using Smoothed Particle Hydrodynamics and Viscosity Behavior
- Author(s):
- Xing Zheng and Wen-yang Duan
- Affilations:
- DOI:
- -
- Abstract:
- Smoothed particle hydrodynamics (SPH) is a Lagrangian meshless particle method. It is one of the best method for simulating violent free surface flows in fluids and solving large fluid deformations. Dam breaking is a typical example of these problems. The basis of SPH was reviewed, including some techniques for governing equation resolution, such as the stepping method and the boundary handling method. Then numerical results of a dam breaking simulation were discussed, and the benefits of concepts like artificial viscosity and position correction were analyzed in detail. When compared with dam breaking simulated by the volume of fluid (VOF) method, the wave profile generated by SPH had good agreement, but the pressure had only reasonable agreement. Improving pressure results is clearly an important next step for research.
References:
Colagrossi A, Landrini M (2003). Numerical simulation of interfacial flow by smoothed particle hydrodynamics. Journal of Computational Physics, 191(2), 448-475.
Chen HC, Yu K (2009). CFD simulations of wave-current-body interactions including greenwater and wet deck slamming. Computer & Fluids, 38(5), 970-980.
Gingold RA, Monaghan JJ (1977). Smoothed particle hydrodynamics: theory and applications to non-spherical stars. Mon Not Roy Astrou Soc, 181, 375-389.
Hu CH, Kashiwagi M (2004). A CIP-based method for numerical simulations of violent free-surface flows. Journal of Marine Science and Technology, 9(4), 143-157. Koshizuka S, Nobe A, Oka Y (1998). Numerical analysis of breaking waves using the moving particle semi-implicit method. International Journal for Numerical Methods in Fluids, 26(7), 751-769.
Lucy LB (1977). A numerical approach to the testing of the fission hypothesis. The Astronomical Journal, 8(12), 1013- 1024.
Lo EYM, Shao SD (2002). Simulation of near-shore solitary wave mechanics by an incompressible SPH method. Applied Ocean Research, 24(5), 275-286.
Monaghan JJ (1992). Smoothed Particle Hydrodynamics. Annual Review Astronomy & Astro-physics, 30, 543-574.
Monaghan JJ (1994). Simulating free surface flows with SPH. Journal of Computational Physics, 110(2), 399-406.
Morris JP (1997). Modeling low Reynolds number incompressible flow using SPH. Journal of Computational Physics, 136(1), 214-226.
Souto IA, Perez RL, Zamora RR (2004). Simulation of anti-roll tanks and sloshing type problems with smoothed particle hydrodynamics. Ocean Engineering, 31(8-9), 1169-1192.
Souto IA, Delorme L, Perez RL, Abril PS (2006). Liquid moment amplitude assessment in sloshing type problems with smooth paritcle hydrodynamics. Ocean Eengineering, 33(11-12), 1462-1484.
Takeda H, Miyama SM, Sekiya M (1994). Numerical simulation of viscous flow by smoothed particle hydrodynamics. Progress of Theoretical Physics, 92(5), 939-960.
Xu Gang, Duan Wenyang (2008). Time domain simulation for water wave radiation by floating structures. Journal of Marine Science of Application, 7(4), 226-235.
Xu Guodong, Duan Wenyang (2009). Review of prediction techniques on hydrodynamic impact of ships. Journal of Marine Science of Application, 8(3), 204-210.
Memo
- Memo:
- -
