Turbulent Fluid Flow

A guide to the essential information needed to model and compute turbulent flows and interpret experiments and numerical simulations Turbulent Fluid Flow offers an authoritative resource to the theories and models encountered in the field of turbulent flow. In this book, the author - a noted expert...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Bernard, Peter S.
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Newark : John Wiley & Sons, Incorporated, 2018.
Temas:
Turbulence.
Fluid dynamics.
Hydrodynamics
Dynamique des fluides.
SCIENCE > Mechanics > Dynamics.
Fluid dynamics
Turbulence
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover; Title Page; Copyright; Contents; Preface; About the Companion Website; Chapter 1 Introduction; 1.1 What is Turbulent Flow?; 1.2 Examples of Turbulent Flow; 1.3 The Goals of a Turbulent Flow Study; 1.4 Overview of the Methodologies Available to Predict Turbulence; 1.4.1 Direct Numerical Simulation; 1.4.2 Experimental Methods; 1.4.3 Turbulence Modeling; 1.5 The Plan for this Book; References; Chapter 2 Describing Turbulence; 2.1 Navier-Stokes Equation and Reynolds Number; 2.2 What Needs to be Measured and Computed; 2.2.1 Averaging; 2.2.2 One-Point Statistics; 2.2.3 Two-Point Correlations
  • 4.5 Structure Functions4.6 Chapter Summary; References; Chapter 5 Energy Decay in Isotropic Turbulence; 5.1 Energy Decay; 5.1.1 Turbulent Reynolds Number; 5.2 Modes of Isotropic Decay; 5.3 Self-Similarity; 5.3.1 Fixed Point Analysis; 5.3.2 Final Period of Isotropic Decay; 5.3.3 High Reynolds Number Equilibrium; 5.4 Implications for Turbulence Modeling; 5.5 Equation for Two-Point Correlations; 5.6 Self-Preservation and the Kármán-Howarth Equation; 5.7 Energy Spectrum Equation; 5.8 Energy Spectrum Equation via Fourier Analysis of the Velocity Field; 5.8.1 Fourier Analysis on a Cubic Region
  • 5.8.2 Limit of Infinite Space5.8.3 Applications to Turbulence Theory; 5.9 Chapter Summary; References; Chapter 6 Turbulent Transport and its Modeling; 6.1 Molecular Momentum Transport; 6.2 Modeling Turbulent Transport by Analogy to Molecular Transport; 6.3 Lagrangian Analysis of Turbulent Transport; 6.4 Transport Producing Motions; 6.5 Gradient Transport; 6.6 Homogeneous Shear Flow; 6.7 Vorticity Transport; 6.7.1 Vorticity Transport in Channel Flow; 6.8 Chapter Summary; References; Chapter 7 Channel and Pipe Flows; 7.1 Channel Flow; 7.1.1 Reynolds Stress and Force Balance
  • 7.1.2 Mean Flow Similarity7.1.3 Viscous Sublayer; 7.1.4 Intermediate Layer; 7.1.5 Velocity Moments; 7.1.6 Turbulent Kinetic Energy and Dissipation Rate Budgets; 7.1.7 Reynolds Stress Budget; 7.1.8 Enstrophy and its Budget; 7.2 Pipe Flow; 7.2.1 Mean Velocity; 7.2.2 Power Law; 7.2.3 Streamwise Normal Reynolds Stress; References; Chapter 8 Boundary Layers; 8.1 General Properties; 8.2 Boundary Layer Growth; 8.3 Log-Law Behavior of the Velocity Mean and Variance; 8.4 Outer Layer; 8.5 The Structure of Bounded Turbulent Flows; 8.5.1 Development of Vortical Structure in Transition

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