Ocean Engineering Research AdvancesAlan I. Prescott Nova Publishers, 2008 - 334 頁 Ocean engineering is the branch of engineering concerned with the design, analysis and operation planning of systems that operate in an oceanic environment. Examples of systems range from oil platforms to submarines, from breakwaters to sailboats. Common to all are the conditions of the ocean including waves, seawater, and hydrostatic pressure. The ocean environment presents a vast quantity of renewable sources of energy in the form of winds, waves, tides, currents and the density and thermal gradients between ocean water layers. This book presents leading-edge research in ocean engineering. |
內容
1 | |
EXPLOITING THE DEEP OCEANS FOR ENERGY RESOURCES AND THE PREVENTION OF ENVIRONMENTAL MELTDOWN | 49 |
AN IMPROVEMENT IN AIS THE PREDICTION ABILITY ABOUT THE SHIPS COURSE | 57 |
HYSTERETIC CHARACTERISTICS OF THE WELLS TURBINE FOR WAVE POWER CONVERSION | 89 |
RANDOM WAVEINDUCED PORE PRESSURE AND EFFECTIVE STRESSES IN A POROUS SEABED | 113 |
COUPLED RANSBOUSSINESQ SCHEME FOR EFFICIENT SOLUTIONS OF WAVE ACTION ON COASTAL STRUCTURES | 167 |
FORCED VIBRATIONS OF RECTANGULAR ANISOTROPIC PLATES IN AN OCEAN STRUCTURE | 185 |
A 2D HYDRODYNAMIC MODEL WITH MULTIQUADTREE MESH | 215 |
QUAD TREE BASED NUMERICAL MODEL FOR COASTAL HYDRODYNAMICS SIMULATION | 253 |
RECENT ADVANCES IN NUMERICAL SIMULATIONS FOR INTERACTION OF VISCOUS TRAVELLING WAVE WITH STRUCTURES IN NE... | 279 |
A TYPHOONHURRICANE SWELL PREDICTION SCHEME | 312 |
Index | 324 |
常見字詞
accelerating amplitude analytical solutions anisotropic B-M spectrum b₁ bathymetry blade bottom boundary conditions Boussinesq Boussinesq equations breakwater calculated carbon dioxide cell coefficient computational decelerating flow deep stall deep stall condition Dimensionless distribution domain dynamic equations experimental finite soil finite volume fluid free surface frequency grid hydrodynamic hysteretic hysteretic characteristics JONSWAP spectrum K₁ K₂ maximum methane hydrates method multi-quadtree mesh neural networks nonlinear Nova Science Publishers numerical model oceans parameters plate subjected pore pressure predicted present pressure hull quadtree random wave rectangular region regular wave Ritz method Ross scheme seabed shallow water equations shear stress ship shown in Figure simulation slopping bed Smax soil thickness solitary wave structure suction surface surface elevation Table turbine typhoon underwater values variable vertical vessel vibrations wave breaking wave height wave loading wave period wave train wave-induced soil response ду дх
熱門章節
第 5 頁 - If, however, the ring stiffeners are not strong enough, the entire ring-shell combination can buckle bodily through general instability, as shown in Figure 4.
第 4 頁 - Introduction The pressure hulls of submarines and the legs of off-shore drilling rigs are often constructed from thin-walled circular cylinders. Now under external water pressure, a thin-walled circular cylinder can buckle at a small fraction of the pressure to cause axisy mmetric yield.