3D hydroelastic modelling of fluid–structure interactions of porous flexible structures

A 3D hydroelastic model subjected to linear wave interaction with horizontal flexible floating and submerged porous structures is developed. The dispersion relation of the aforesaid problem is derived based on Green’s functions approach in water of finite and infinite depths. Three-dimensional Fouri...

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Bibliographic Details
Published in:Journal of fluids and structures 2022-07, Vol.112, p.103588, Article 103588
Main Authors: Mohapatra, S.C., Guedes Soares, C.
Format: Article
Language:English
Subjects:
Dispersion relation
Expansion formulae
Flexible plate
Green’s function
Mooring lines
Porous plate
Three-dimensional hydroelastic model
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Summary:A 3D hydroelastic model subjected to linear wave interaction with horizontal flexible floating and submerged porous structures is developed. The dispersion relation of the aforesaid problem is derived based on Green’s functions approach in water of finite and infinite depths. Three-dimensional Fourier-type expansion formulae for the velocity potentials associated with orthogonal mode-coupling relations are derived in a channel of finite and infinite water depths of finite width. A real physical problem of surface gravity wave interaction with a moored floating and submerged porous plate in finite water depth is analysed by the expansion formula to validate the usefulness of the current method. The numerical accuracy of the present numerical results is checked via convergence test. Further, the effect of different design parameters on the hydroelastic response of floating and a submerged porous plate is studied by analysing the deflection amplitude and structural deformation. It is observed that the present analysis could be useful for a greater insight to design a multi-use flexible floating system.
ISSN:0889-9746
1095-8622
DOI:10.1016/j.jfluidstructs.2022.103588