Hydrodynamic behaviour of floating polygonal compound platforms with wide porous media

Presented herein are the formulation and semi-analytical solutions for the hydrodynamic characteristics and wave fields of floating polygonal compound platforms with wide porous media. The wetted porous medium is assumed to be homogeneous and fully saturated. Limiting cases of the semi-analytical so...

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Bibliographic Details
Published in:Ocean engineering 2022-12, Vol.265, p.112672, Article 112672
Main Authors: Park, J.C., Wang, C.M., Cho, I.H.
Format: Article
Language:English
Subjects:
3D hydrodynamic analysis
Cosine-type radial perturbation
Eigenfunction expansion method
Floating polygonal compound platform
Fourier expansion
Porous medium
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Summary:Presented herein are the formulation and semi-analytical solutions for the hydrodynamic characteristics and wave fields of floating polygonal compound platforms with wide porous media. The wetted porous medium is assumed to be homogeneous and fully saturated. Limiting cases of the semi-analytical solutions without the porous medium have been verified by the results obtained by using the commercial software ANSYS AQWA. The present semi-analytical solutions based on a matched eigenfunction expansion method are useful as benchmark results for analysts working on new numerical methods for the hydrodynamic analysis of floating platforms with porous media. Parametric studies were conducted to examine the effects of porous media on the wave exciting forces, RAOs, wave fields, porous damping and mooring loads. It is found that the wide porous medium with appropriate porosity and resistance coefficient contributes to reducing the wave exciting forces, RAOs, and overall level of wave fields in the long period region by attenuating the incident wave energy. Also, the porous medium helps to decrease the mooring loads, especially at resonance. Thus, a wide porous medium surrounding the compound platform is effective in both enhancing the motion performance of the floating platform and reducing the wave fields around it. •Formulation for 3D hydrodynamic analysis of floating polygonal compound platform with wide porous media.•Suggestion of how to obtain the wave exciting forces and porous damping with the associated derivation.•Investigation of improved hydrodynamic performances of floating structures with porous media.
ISSN:0029-8018
1873-5258
DOI:10.1016/j.oceaneng.2022.112672