A fast convergent modal-expansion of the wave potential with application to the hydrodynamic and hydroelastic analysis of floating bodies in general bathymetry

A non-linear coupled-mode system of horizontal equations has been derived with the aid of Luke's (1967) variational principle, modelling the evolution of nonlinear water waves in intermediate depth and over a general bathymetry Athanassoulis & Belibassakis (2002, 2008). Following previous w...

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Bibliographic Details
Main Authors: Belibassakis, KA, Athanassoulis, GA
Format: Conference Object
Language:unknown
Published: 2009
Subjects:
Additional mode
Cnoidal wave
Elastic body
Evanescent mode
Flexural rigidities
Floating bodies
Floating structures
Free surfaces
General bathymetry
Hydro-elastic analysis
Hydrodynamic and hydroelastic analysis
Ice sheet
Intermediate depths
Mass distribution
Non-linear
Non-Linearity
Nonlinear travelling waves
Nonlinear water waves
Numerical example
Numerical investigations
Numerical solution
Series expansion
Thin plate
Variable bathymetry
Variable thickness
Variational principles
Vertical structures
Wave potentials
Wavefields
Arctic engineering
Bathymetry
Hydrodynamics
Nonlinear equations
Numerical analysis
Oceanography
Offshore structures
Rigid structures
Thickness control
Variational techniques
Water waves
Waves
Hydroelasticity
Arctic
Ice Sheet
Online Access:http://dspace.lib.ntua.gr/handle/123456789/35742
Description
Summary:A non-linear coupled-mode system of horizontal equations has been derived with the aid of Luke's (1967) variational principle, modelling the evolution of nonlinear water waves in intermediate depth and over a general bathymetry Athanassoulis & Belibassakis (2002, 2008). Following previous work by the authors in the case of linearised water waves (Athanassoulis & Belibassakis 1999), the vertical structure of the wave field is exactly represented by means of a local-mode series expansion of the wave potential. This series contains the usual propagating and evanescent modes, plus two additional modes, the free-surface mode and the sloping-bottom mode, enabling to consistently treat the non-vertical end-conditions at the free-surface and the bottom boundaries. The coupled-mode system fully accounts for the effects of non-linearity and dispersion. The main feature of this approach that a small number of modes (of the order of 5-6) are enough for the precise numerical solution, provided that the two new modes (the free-surface and the sloping-bottom ones) are included in the local-mode series. The consistent coupled-mode system has been applied to numerical investigation of families of steady nonlinear travelling wave solutions in constant depth (Athanassoulis & Belibassakis 2007) showing good agreement with known solutions both in the Stokes and the cnoidal wave regimes. In the present work we focus on the hydroelastic analysis of floating bodies lying over variable bathymetry regions, with application to the non-linear scattering of water waves by large floating structures (of VLFS type or ice sheets) characterised by variable thickness (draft), flexural rigidity and mass distributions, modelled as thin plates of variable thickness, extending previous approaches (see, e.g., Porter & Porter 2004, Belibassakis & Athanassoulis 2005, 2006, Bennets et al 2007). Numerical examples are presented, showing that useful results can be obtained for the analysis of large floating elastic bodies or structures very efficiently by keeping only a few terms in the expansion. Ideas for extending our approach to 3D are also discussed. Copyright © 2009 by ASME.

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