RANS Simulation of Viscous Flow around Hull of Multipurpose Amphibious Vehicle
Authors: M. Nakisa, A. Maimun, Yasser M. Ahmed, F. Behrouzi, A. Tarmizi
Abstract:
The practical application of the Computational Fluid Dynamics (CFD), for predicting the flow pattern around Multipurpose Amphibious Vehicle (MAV) hull has made much progress over the last decade. Today, several of the CFD tools play an important role in the land and water going vehicle hull form design. CFD has been used for analysis of MAV hull resistance, sea-keeping, maneuvering and investigating its variation when changing the hull form due to varying its parameters, which represents a very important task in the principal and final design stages. Resistance analysis based on CFD (Computational Fluid Dynamics) simulation has become a decisive factor in the development of new, economically efficient and environmentally friendly hull forms. Three-dimensional finite volume method (FVM) based on Reynolds Averaged Navier-Stokes equations (RANS) has been used to simulate incompressible flow around three types of MAV hull bow models in steady-state condition. Finally, the flow structure and streamlines, friction and pressure resistance and velocity contours of each type of hull bow will be compared and discussed.
Keywords: RANS Simulation, Multipurpose Amphibious Vehicle, Viscous Flow Structure.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1090693
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[1] T. Hino, "Proceedings of the CFD Workshop Tokyo 2005”, Tokyo, Japan, 2005.
[2] Y. Kodoma, H. Takeshi, M. Hinatsu, T. Hino, S.Uto, N. Hirata and S. Murashige, "Proceedings of the 1994 CFD Workshop”, Ship Research Institute, Japan, 1994.
[3] L. Larsson, F. Stern and V. Bertram, "Benchmarking of Computational Fluid Dynamics for Ship Flows: The Gothenburg 2000 Workshop”, Journal of Ship Research, 2003, vol. 47, iss. 1, pp. 63-81.
[4] R.A. Repetto, "Computation of Turbulent Free-Surface Flows Around Ships and Floating Bodies”, PhD. Thesis, Technical University Hamburg-Harburg, Argentina, 2001.
[5] D.A. Jones and D.B. Clarke, "Fluent Code Simulation of Flow around a Naval Hull: The DTMB 5415”, Maritime Platforms Division, Defence Science and Technology Organisation, Australian Government, Department of Defence, 2010.
[6] D.F. Mucientes, "Numerical Simulation of Free Surface Viscous Flows around Single and Multiple Hulls”, M.S Thesis, Department of Mechanical and Aerospace Engineering, California State University, Long Beach, December, 2010.
[7] S.H. Rhee, "Unsteady Reynolds Averaged Navier-Stokes Method for Free-Surface Wave Flows Around Surface-Piercing Cylindrical Structures”, Journal of Waterway, Port, Coastal and Ocean Engineering, 2009.
[8] S.H. Rhee, B. P. Makrov, H. Krishinan, and V. Ivanov, "Assessment of the Volume of Fluid Method for Free Surface Wave Flow”, Journal of Marine Science and Technology, 2005, vol. 10, pp. 173-180.
[9] J.G. Sticker, A.J. Becnel and J.G. Purnell, Advanced Waterjet Systems. Nav. Eng. J. 106 (5), 1994, pp. 100–109.
[10] A. Maimun, A., M. Y. Ahmed., A. Priyanto, Y. S. Ang., M. Nakisa., "Assessment of Ship-Bank Interactions on LNG Tanker in Shallow Water”, Department of Marine Technology, University Technology Malaysia, Johor Bahru, Malaysia, The 6th Asia-Pacific Workshop on Marine Hydrodymics-PHydro2012Malaysia,September 3-4, 2012.