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Basics of engineering turbulence /

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Ting, David
Formato: Electrónico eBook
Idioma:Inglés
Publicado: London, UK L : Academic Press, 2016.
Temas:
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover; Title Page; Copyright Page; Dedication; Contents; List of Figures; List of Tables; Acknowledgments; Foreword; Preface; Part 1
  • Some Basics of Flow Turbulence; Chapter 1
  • Introducing Flow Turbulence; Chapter Objectives; Nomenclature; 1.1
  • Introduction; 1.1.1
  • Irregular or Random; 1.1.2
  • Rich in Scales of Eddying Motion; 1.1.3
  • Large Reynolds Number; 1.1.4
  • Dissipative; 1.1.5
  • Highly Vortical; 1.1.6
  • Three-Dimensional; 1.1.7
  • Highly Diffusive; 1.1.8
  • Turbulent Flows are Flows; 1.1.9
  • Continuum; 1.2
  • A brief historic account; 1.2.1
  • Leonardo da Vinci (1452-1519).
  • 1.2.2
  • Lord Rayleigh (1878, 1880)1.2.3
  • Osborne Reynolds (1842-1912); 1.2.4
  • Henri Bénard (1900); 1.2.5
  • Taylor (1915, 1923, 1935, 1938); 1.2.6
  • Prandtl (1925); 1.3
  • Organization of the book; References; Chapter 2
  • Equations of Fluid in Motion; Chapter Objectives; Nomenclature; 2.1
  • Introduction; 2.2
  • Eulerian and Lagrangian frames; 2.2.1
  • Eulerian; 2.2.2
  • Lagrangian; 2.2.3
  • Eulerian-Lagrangian Transformation; 2.3
  • Common equations in fluid mechanics; 2.3.1
  • Conservation of Mass; 2.3.2
  • Momentum Equation; 2.4
  • Reynolds decomposition.
  • 2.5
  • Conservation of mass from laminar to turbulent flow2.6
  • Momentum equation in turbulent flow; References; Chapter 3
  • Statistical Description of Flow Turbulence; Chapter Objectives; Nomenclature; 3.1
  • Introduction; 3.2
  • Probability; 3.3
  • Moments; 3.4
  • Joint statistics and correlation functions; 3.5
  • Additional considerations; 3.5.1
  • Fourier Series and Coefficients; 3.5.2
  • Fourier Transforms and Characteristic Functions; References; Chapter 4
  • Turbulence Scales; Chapter Objectives; Nomenclature; 4.1
  • Introduction.
  • 4.2
  • Velocity and key length scales in laminar and turbulent boundary layers4.2.1
  • Laminar Boundary Layer; 4.2.2
  • Turbulent Boundary Layer; 4.3
  • Molecular versus turbulent diffusion; 4.4
  • Kolmogorov microscales of dissipation; 4.5
  • An inviscid estimate for dissipation rate; 4.6
  • The energy cascade
  • scales from production-dissipation energy balance; 4.6.1
  • Production, Dissipation, and Local Equilibrium; 4.6.2
  • Approximate Scaling of Production and Dissipation; 4.6.3
  • Relating Production and Dissipation Scales; 4.7
  • Refined estimates for turbulence dissipation and integral scales.