Proceedings of the ... International Conference on Offshore Mechanics and Arctic Engineering, Volume 2; Volume 7, Part 2American Society of Mechanical Engineers, 1988 - Arctic regions |
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Page 159
BREAKING WAVES AT SEA : MODELLING AND APPLICATIONS M. P. Tulin Ocean Engineering Laboratory University of California at Santa Barbarba Santa Barbarba , California R. Cointe Institut Francais du Petrole Rueil Malmaison , France 159 The ...
BREAKING WAVES AT SEA : MODELLING AND APPLICATIONS M. P. Tulin Ocean Engineering Laboratory University of California at Santa Barbarba Santa Barbarba , California R. Cointe Institut Francais du Petrole Rueil Malmaison , France 159 The ...
Page 167
... Breaking is also seen to increase rapidly with wind friction velocity ( ux ) , as suggested by Wu ( 1979 ) , based on an overall equilibrium between wind energy input and dissipation due to breaking , and in agreement with data on ...
... Breaking is also seen to increase rapidly with wind friction velocity ( ux ) , as suggested by Wu ( 1979 ) , based on an overall equilibrium between wind energy input and dissipation due to breaking , and in agreement with data on ...
Page 172
... breaking waves on a probabilistic basis to determine such factors as the probability of a breaking event ( temporally or spatially ) , the proportion of sea sur- face under whitecap coverage , relational characterist- ics between ...
... breaking waves on a probabilistic basis to determine such factors as the probability of a breaking event ( temporally or spatially ) , the proportion of sea sur- face under whitecap coverage , relational characterist- ics between ...
Contents
HYDRODYNAMIC FORCESI | 1 |
Catchment Regions of Multiple Dynamic Responses in Nonlinear Problems of Offshore Mechanics | 15 |
OFFSHORE TECHNOLOGY GEOTECHNICAL ENGINEERING | 21 |
Copyright | |
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acting amplitude analysis angle applied approximately assumed body boundary breaker breaking calculated coefficient compared comparison component computed considered corresponding cylinder damping density depend depth determined diameter direction distribution drag drift force dynamic effects elevation energy Engineering equation estimated excitation experimental experiments expressed field Figure flow fluid free surface frequency function given horizontal hydrodynamic incident increase integral irregular length linear load mass maximum mean measured Mechanics method motion obtained Ocean Offshore oscillation parameters period phase potential predicted present pressure probability problem range ratio region regular waves relative Research respectively response second order shear ship shown shows simulation solution spectra spectrum structure surface Table theory values velocity vertical vortex wave drift wave forces wave height wind