The boundary value problem is formulated to predict the hydroelastic response of a matlike floating circular plate advancing slowly in waves. The plate is idealized as an elastic plate with zero draught, and the potential flow theory is employed with low forward-speed assumptions. These assumptions allow the steady disturbance potential due to forward speed to be neglected, simplifying the problem considerably. By applying the eigenfunction-expansion domain-matching method, analytical solutions are derived for the scattering and radiation potentials up to the leading-order terms of the speed-dependent parts. The far-field approach is adopted to obtain the expression for the wave drift force. Numerical results are also presented for the typical plate geometry, which demonstrates the significant effect of the forward speed on the hydroelastic response and wave drift force.

Issue Section:
Technical Papers
Keywords:
elasticity, plates (structures), boundary-value problems, offshore installations, water waves, eigenvalues and eigenfunctions, very large floating structure, hydroelastic response, forward speed, wave-current interaction, wave drift damping, towing
Topics:
Boundary-value problems, Electromagnetic scattering, Radiation scattering, Scattering (Physics), Wave drift forces, Waves, Radiation (Physics), Damping, Wave drift, Eigenfunctions
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 by American Society of Mechanical Engineers
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