Nonlinear force calculations by Numerical Wave Tank simulations Conference Paper uri icon

abstract

  • Fully nonlinear wave interactions with a three-dimensional body in the presence of steady uniform currents are studied using two independent Numerical Wave Tanks (NWT). The potential-NWT simulations are compared with the viscous-NWT simulations. The potential NWT used an indirect Desingularized Boundary Integral Equation Method (DBIEM) and a Mixed Eulerian-Lagrangian (MEL) time marching scheme. The Laplace equation is solved at each time step and the fully nonlinear free surface boundary conditions are integrated with time. A regridding algorithm is devised to eliminate the possible saw-tooth instabilities. The incident waves are generated by a piston-type wavemaker. The outgoing waves are dissipated inside a damping zone by using spatially varying artificial damping on the free surface. The viscous NWT solves a Navier-Stokes (NS) equation by using a finite-difference scheme and a modified marker-and cell (MAC) method in the frame of rectangular-coordinate system. The fully-nonlinear kinematic free-surface condition is satisfied by the density-function technique developed for two fluid layers. Computations are performed for the nonlinear diffractions of steep monochromatic waves by a truncated vertical cylinder with/without uniform currents. The NWT simulations compared favorably with available experimental results.

published proceedings

  • Proceedings of the International OTRC Symposium

author list (cited authors)

  • Kim, M. H., Celebi, M. S., & Park, J. C.

complete list of authors

  • Kim, MH||Celebi, MS||Park, JC

publication date

  • January 1998