Fundamentals of ship hydrodynamics : fluid mechanics, ship resistance and propulsion /

Fundamentals of Ship Hydrodynamics: Fluid Mechanics, Ship Resistance and Propulsion Lothar Birk, University of New Orleans, USA Bridging the information gap between fluid mechanics and ship hydrodynamics Fundamentals of Ship Hydrodynamics is designed as a textbook for undergraduate education in ship...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Birk, Lothar, 1963- (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Hoboken, NJ : John Wiley & Sons, Ltd, [2019]
Temas:
Ships > Hydrodynamics.
Navires > Hydrodynamique.
TECHNOLOGY & ENGINEERING > Military Science.
Vaixells > Hidrodinàmica.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover; Title Page; Copyright; Dedication; Contents; List of Figures; List of Tables; Preface; Acknowledgments; About the Companion Website; chapter 1 Ship Hydrodynamics; 1.1 Calm Water Hydrodynamics; 1.2 Ship Hydrodynamics and Ship Design; 1.3 Available Tools; chapter 2 Ship Resistance; 2.1 Total Resistance; 2.2 Phenomenological Subdivision; 2.3 Practical Subdivision; 2.3.1 Froude's hypothesis; 2.3.2 ITTC's method; 2.4 Physical Subdivision; 2.4.1 Body forces; 2.4.2 Surface forces; 2.5 Major Resistance Components; chapter 3 Fluid and Flow Properties; 3.1 A Word on Notation
  • 3.2 Fluid Properties3.2.1 Properties of water; 3.2.2 Properties of air; 3.2.3 Acceleration of free fall; 3.3 Modeling and Visualizing Flow; 3.4 Pressure; chapter 4 Fluid Mechanics and Calculus; 4.1 Substantial Derivative; 4.2 Nabla Operator and Its Applications; 4.2.1 Gradient; 4.2.2 Divergence; 4.2.3 Rotation; 4.2.4 Laplace operator; chapter 5 Continuity Equation; 5.1 Mathematical Models of Flow; 5.2 Infinitesimal Fluid Element Fixed in Space; 5.3 Finite Control Volume Fixed in Space; 5.4 Infinitesimal Element Moving With the Fluid; 5.5 Finite Control Volume Moving With the Fluid
  • 5.6 Summarychapter 6 Navier-Stokes Equations; 6.1 Momentum; 6.2 Conservation of Momentum; 6.2.1 Time rate of change of momentum; 6.2.2 Momentum flux over boundary; 6.2.3 External forces; 6.2.4 Conservation of momentum equations; 6.3 Stokes' Hypothesis; 6.4 Navier-Stokes Equations for a Newtonian Fluid; chapter 7 Special Cases of the Navier-Stokes Equations; 7.1 Incompressible Fluid of Constant Temperature; 7.2 Dimensionless Navier-Stokes Equations; chapter 8 Reynolds Averaged Navier-Stokes Equations (RANSE); 8.1 Mean and Turbulent Velocity; 8.2 Time Averaged Continuity Equation
  • 8.3 Time Averaged Navier-Stokes Equations8.4 Reynolds Stresses and Turbulence Modeling; chapter 9 Application of the Conservation Principles; 9.1 Body in a Wind Tunnel; 9.2 Submerged Vessel in an Unbounded Fluid; 9.2.1 Conservation of mass; 9.2.2 Conservation of momentum; chapter 10 Boundary Layer Theory; 10.1 Boundary Layer; 10.1.1 Boundary layer thickness; 10.1.2 Laminar and turbulent flow; 10.1.3 Flow separation; 10.2 Simplifying Assumptions; 10.3 Boundary Layer Equations; chapter 11 Wall Shear Stress in the Boundary Layer; 11.1 Control Volume Selection
  • 11.2 Conservation of Mass in the Boundary Layer11.3 Conservation of Momentum in the Boundary Layer; 11.3.1 Momentum flux over boundary of control volume; 11.3.2 Surface forces acting on control volume; 11.3.3 Displacement thickness; 11.3.4 Momentum thickness; 11.4 Wall Shear Stress; chapter 12 Boundary Layer of a Flat Plate; 12.1 Boundary Layer Equations for a Flat Plate; 12.2 Dimensionless Velocity Profiles; 12.3 Boundary Layer Thickness; 12.4 Wall Shear Stress; 12.5 Displacement Thickness; 12.6 Momentum Thickness; 12.7 Friction Force and Coefficients; chapter 13 Frictional Resistance

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