Abstract
The hydroelastic response of an elastic thin plate combined with a vertical porous flexible plate floating on a single- or a two-layer fluid is analyzed in the two-dimensional Cartesian coordinate system. The vertical and the horizontal plates are placed in an inverted-L shape and rigidly connected together. The problem is studied with the aid of the method of matched eigenfunction expansions within the framework of linear potential flow theory. The fluid is assumed to be inviscid and incompressible, and the motion is assumed to be irrotational. Time–harmonic incident waves of the traveling mode with a given angular frequency are considered. Then, the least-squares approximation method and the inner product are used to obtain the expansion coefficients of the velocity potentials. Graphical results show the interaction between the water waves and the structure. The effects of several physical parameters, including the length and the complex porous-effect parameter of the vertical plate, on the wave reflection and transmission are discussed. The results show that a vertical plate can effectively eliminate the hydroelastic response of the very large floating structure. The longer a vertical plate is, the more waves are reflected by the vertical plate. With the increase in the porous-effect parameter, the deflection of vertical plate decreases. Besides the effects of the flexural rigidity, the lateral stress, the mooring line angle, the fluid density ratio, and the position of interface on the wave reflection and transmission are discussed. Numerical results show the significant mitigation effect due to the presence of the additional vertical plate.
Highlights
A simple and effective anti-motion device is a submerged vertical plate attached with a Very large floating structures (VLFSs), and it has been widely studied to suppress the hydroelastic response of a VLFS
We investigate the hydroelastic responses of a semi-infinite floating plate combined with a vertical porous flexible plate under the wave action on a single-layer or a two-layer fluid of finite depth with the aid of the method of matched eigenfunction expansions (MMEE)
We have analytically studied the hydroelastic response of semi-infinite and finite floating elastic plate combined with a vertical elastic porous plate in a single-layer and a two-layer fluids with the aid of the method of matched eigenfunction expansions
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. A simple and effective anti-motion device is a submerged vertical plate attached with a VLFS, and it has been widely studied to suppress the hydroelastic response of a VLFS. The finite element–boundary element method is utilized in research of a Wave Energy Converter (WEC)-type attachment to reduce hydroelastic responses of the VLFS [11,12]. Kumar and Sahoo [23] studied the performance of a flexible porous plate breakwater in a two-layer fluid via the least-squares approximation method which is widely used in research of vertical barrier. We investigate the hydroelastic responses of a semi-infinite floating plate combined with a vertical porous flexible plate under the wave action on a single-layer or a two-layer fluid of finite depth with the aid of the MMEE.
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