Proceedings of the ... International Conference on Offshore Mechanics and Arctic Engineering, Volume 5American Society of Mechanical Engineers, 2007 - Arctic regions |
From inside the book
Results 1-3 of 50
Page 329
... nonlinear numerical wave tank model has been used to simulate the propagation of fully nonlinear waves in different water depths . In the numerical wave tank model , the fully nonlinear dynamic and kinematic free - surface boundary ...
... nonlinear numerical wave tank model has been used to simulate the propagation of fully nonlinear waves in different water depths . In the numerical wave tank model , the fully nonlinear dynamic and kinematic free - surface boundary ...
Page 336
CONCLUSIONS The nonlinear wave propagation in deepwater , transition zone and in shallow - water has been well simulated using a fully nonlinear numerical wave tank model . The model solution has been verified through the comparison ...
CONCLUSIONS The nonlinear wave propagation in deepwater , transition zone and in shallow - water has been well simulated using a fully nonlinear numerical wave tank model . The model solution has been verified through the comparison ...
Page 363
... nonlinear wave spectra . Maximum nonlinear correction is about 10 % in an average simulated sea . However , the nonlinear correction could be as much as 50 % in a design level sea state , because the 2nd order correction is proportional ...
... nonlinear wave spectra . Maximum nonlinear correction is about 10 % in an average simulated sea . However , the nonlinear correction could be as much as 50 % in a design level sea state , because the 2nd order correction is proportional ...
Contents
OCEAN SPACE UTILIZATION | 1 |
OMAE200729521 | 11 |
OMAE200729557 | 17 |
Copyright | |
68 other sections not shown
Other editions - View all
Common terms and phrases
26th International Conference aircushion amplitude analysis ASME bathymetry Bay of Fundy beach boundary conditions Bragg scattering breakwater buoy calculated cavitation Coastal coefficient computed Conference on Offshore Copyright 2007 density developed device diameter displacement dynamic effect element equation experimental floating body units flow fluid force frequency function gouge grout hydrodynamic ice load increase installed interaction linear Makran marine maximum measured Mechanics and Arctic method monopile motion mussels nonlinear Ocean ocean energy Offshore Mechanics offshore wind turbine optimization parameters pile pipe pipeline platform pontoon potential predicted pressure problem ratio Research response rotor scale scour depth seabed shown in Figure shrimp significant wave height simulation stray children stress structure Technology tidal power tower tsunami velocity velocity potential vertical Von Mises stress vortex water depth wave energy wave power width wind farms wind speed