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http://dx.doi.org/10.2478/IJNAOE-2013-0174

Numerical analysis of two and three dimensional buoyancy driven water-exit of a circular cylinder  

Moshari, Shahab (Department of Mechanical and Aerospace Engineering, Shiraz University of Technology)
Nikseresht, Amir Hossein (Department of Mechanical and Aerospace Engineering, Shiraz University of Technology)
Mehryar, Reza (Department of Mechanical and Aerospace Engineering, Shiraz University of Technology)
Publication Information
International Journal of Naval Architecture and Ocean Engineering / v.6, no.2, 2014 , pp. 219-235 More about this Journal
Abstract
With the development of the technology of underwater moving bodies, the need for developing the knowledge of surface effect interaction of free surface and underwater moving bodies is increased. Hence, the two-phase flow is a subject which is interesting for many researchers all around the world. In this paper, the non-linear free surface deformations which occur during the water-exit of a circular cylinder due to its buoyancy are solved using finite volume discretization based code, and using Volume of Fluid (VOF) scheme for solving two phase flow. Dynamic mesh model is used to simulate dynamic motion of the cylinder. In addition, the effect of cylinder mass in presence of an external force is studied. Moreover, the oblique exit and entry of a circular cylinder with two exit angles is simulated. At last, water-exit of a circular cylinder in six degrees of freedom is simulated in 3D using parallel processing. The simulation errors of present work (using VOF method) for maximum velocity and height of a circular cylinder are less than the corresponding errors of level set method reported by previous researchers. Oblique exit shows interesting results; formation of waves caused by exit of the cylinder, wave motion in horizontal direction and the air trapped between the waves are observable. In 3D simulation the visualization of water motion on the top surface of the cylinder and the free surface breaking on the front and back faces of the 3D cylinder at the exit phase are observed which cannot be seen in 2D simulation. Comparing the results, 3D simulation shows better agreement with experimental data, specially in the maximum height position of the cylinder.
Keywords
3D simulation; Oblique water-exit; Parallel processing; Free surface; Volume of fluid;
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