Simulation of static sinusoidal wave in deep water environment with complex boundary conditions using proposed SPH method

Authors

  • A. H. Javid Department of Marine Industry, Graduate School of Marine Science and Technology, Science and Research Branch, Islamic Azad University
  • H. JanfeshanAraghi Faculty of Environment and Energy, Science and Research Branch, Islamic Azad University
  • M. Abbaspour Faculty of Mechanics, Sharif University of Technology
  • S. A. Mirbagheri Faculty of Environment and Energy, Science and Research Branch, Islamic Azad University
Abstract:

The study of wave and its propagation on the water surface is among significant phenomena in designing quay, marine and water structures. Therefore, in order to design structures which are exposed to direct wave forces, it is necessary to study and simulate water surface height and the wave forces on the structures body in different boundary conditions. In this study, the propagation of static sinusoidal wave in deep water environment with complex boundary conditions are simulated by using Smoothed Particle Hydrodynamics (SPH) technique. The governing equations are programmed using VISUAL FORTRAN6.5 and the solution results are visualized using TECPLOT. After determining the suitable number of particles for simulation, the duration of sinusoidal wave oscillation are measured by simulation and are compared with analytical solution. After ensuring the accuracy and veracity of proposed SPH method in simulation of static sinusoidal wave motion on the deep water surface, the simulation are carried out in more complex boundary conditions which there are no analytical solutions. 

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Journal title

volume 2  issue 2

pages  141- 148

publication date 2012-06-20

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