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Particles in turbulent flows / / Leonid Zaichik, Vladimir M. Alipchenkov, and Emmanuil G. Sinaiski
| Particles in turbulent flows / / Leonid Zaichik, Vladimir M. Alipchenkov, and Emmanuil G. Sinaiski |
| Autore | Zaichik L. I (Leonid Isaakovich) |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | Weinheim, : Wiley-VCH, c2008 |
| Descrizione fisica | 1 online resource (319 p.) |
| Disciplina | 620.1064 |
| Altri autori (Persone) |
AlipchenkovVladimir M
SinaiskiiE. G (Emmanuil Genrikhovich) |
| Soggetto topico |
Particles - Statistical methods
Turbulence - Statistical methods |
| ISBN |
9786612688706
9781282688704 1282688707 9783527626250 3527626255 9783527626267 3527626263 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Particles in Turbulent Flows; Contents; Preface; Introduction; 1 Motion of Particles and Heat Exchange in Homogeneous Isotropic Turbulence; 1.1 Characteristics of Homogeneous Isotropic Turbulence; 1.2 Motion of a Single Particle and Heat Exchange; 1.3 Velocity and Temperature Correlations in a Fluid along the Inertial Particle Trajectories; 1.4 Velocity and Temperature Correlations for Particles in Stationary Isotropic Turbulence; 1.5 Particle Acceleration in Isotropic Turbulence; 2 Motion of Particles in Gradient Turbulent Flows
2.1 Kinetic Equation for the Single-Point PDF of Particle Velocity2.2 Equations for Single-Point Moments of Particle Velocity; 2.3 Algebraic Models of Turbulent Stresses; 2.3.1 Solution of the Kinetic Equation by the Chapman-Enskog Method; 2.3.2 Solution of the Equation for Turbulent Stresses by the Iteration Method; 2.4 Boundary Conditions for the Equations of Motion of the Disperse Phase; 2.5 Second Moments of Velocity Fluctuations in a Homogeneous Shear Flow; 2.6 Motion of Particles in the Near-Wall Region; 2.6.1 Near-Wall Region Including the Viscous Sublayer 2.6.2 The Equilibrium Logarithmic Layer2.6.3 High-Inertia Particles; 2.7 Motion of Particles in a Vertical Channel; 2.8 Deposition of Particles in a Vertical Channel; 3 Heat Exchange of Particles in Gradient Turbulent Flows; 3.1 The Kinetic Equation for the Joint PDF of Particle Velocity and Temperature; 3.2 The Equations for Single-Point Moments of Particle Temperature; 3.3 Algebraic Models of Turbulent Heat Fluxes; 3.3.1 Solution of the Kinetic Equation by the Chapman-Enskog Method; 3.3.2 Solving the Equation for Turbulent Heat Fluxes by the Iteration Method 3.4 Second Moments of Velocity and Temperature Fluctuations in a Homogeneous Shear Flow4 Collisions of Particles in a Turbulent Flow; 4.1 Collision Frequency of Monodispersed Particles in Isotropic Turbulence; 4.2 Collision Frequency in the Case of Combined Action of Turbulence and the Average Velocity Gradient; 4.3 Particle Collisions in an Anisotropic Turbulent Flow; 4.4 Boundary Conditions for the Disperse Phase with the Consideration of Particle Collisions; 4.5 The Effect of Particle Collisions on Turbulent Stresses in a Homogeneous Shear Flow 4.6 The Effect of Collisions on Particle Motion in a Vertical Channel5 Relative Dispersion and Clustering of Monodispersed Particles in Homogeneous Turbulence; 5.1 The Kinetic Equation for the Two-Point PDF of Relative Velocity of a Particle Pair; 5.2 Equations for Two-Point Moments of Relative Velocity of a Particle Pair; 5.3 Statistical Properties of Stationary Suspension of Particles in Isotropic Turbulence; 5.4 Influence of Clustering on Particle Collision Frequency; 5.5 Relative Dispersion of Two Particles in Isotropic Turbulence; 5.5.1 Dispersion of Inertialess Particles 5.5.2 Dispersion of Inertial Particles |
| Record Nr. | UNINA-9911019081703321 |
Zaichik L. I (Leonid Isaakovich)
|
||
| Weinheim, : Wiley-VCH, c2008 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Particles in turbulent flows [[electronic resource] /] / Leonid Zaichik, Vladimir M. Alipchenkov, and Emmanuil G. Sinaiski
| Particles in turbulent flows [[electronic resource] /] / Leonid Zaichik, Vladimir M. Alipchenkov, and Emmanuil G. Sinaiski |
| Autore | Zaĭchik L. I (Leonid Isaakovich) |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | Weinheim, : Wiley-VCH, c2008 |
| Descrizione fisica | 1 online resource (319 p.) |
| Disciplina | 620.1064 |
| Altri autori (Persone) |
AlipchenkovVladimir M
SinaĭskiĭĖ. G (Ėmmanuil Genrikhovich) |
| Soggetto topico |
Particles - Statistical methods
Turbulence - Statistical methods |
| ISBN |
1-282-68870-7
9786612688706 3-527-62625-5 3-527-62626-3 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Particles in Turbulent Flows; Contents; Preface; Introduction; 1 Motion of Particles and Heat Exchange in Homogeneous Isotropic Turbulence; 1.1 Characteristics of Homogeneous Isotropic Turbulence; 1.2 Motion of a Single Particle and Heat Exchange; 1.3 Velocity and Temperature Correlations in a Fluid along the Inertial Particle Trajectories; 1.4 Velocity and Temperature Correlations for Particles in Stationary Isotropic Turbulence; 1.5 Particle Acceleration in Isotropic Turbulence; 2 Motion of Particles in Gradient Turbulent Flows
2.1 Kinetic Equation for the Single-Point PDF of Particle Velocity2.2 Equations for Single-Point Moments of Particle Velocity; 2.3 Algebraic Models of Turbulent Stresses; 2.3.1 Solution of the Kinetic Equation by the Chapman-Enskog Method; 2.3.2 Solution of the Equation for Turbulent Stresses by the Iteration Method; 2.4 Boundary Conditions for the Equations of Motion of the Disperse Phase; 2.5 Second Moments of Velocity Fluctuations in a Homogeneous Shear Flow; 2.6 Motion of Particles in the Near-Wall Region; 2.6.1 Near-Wall Region Including the Viscous Sublayer 2.6.2 The Equilibrium Logarithmic Layer2.6.3 High-Inertia Particles; 2.7 Motion of Particles in a Vertical Channel; 2.8 Deposition of Particles in a Vertical Channel; 3 Heat Exchange of Particles in Gradient Turbulent Flows; 3.1 The Kinetic Equation for the Joint PDF of Particle Velocity and Temperature; 3.2 The Equations for Single-Point Moments of Particle Temperature; 3.3 Algebraic Models of Turbulent Heat Fluxes; 3.3.1 Solution of the Kinetic Equation by the Chapman-Enskog Method; 3.3.2 Solving the Equation for Turbulent Heat Fluxes by the Iteration Method 3.4 Second Moments of Velocity and Temperature Fluctuations in a Homogeneous Shear Flow4 Collisions of Particles in a Turbulent Flow; 4.1 Collision Frequency of Monodispersed Particles in Isotropic Turbulence; 4.2 Collision Frequency in the Case of Combined Action of Turbulence and the Average Velocity Gradient; 4.3 Particle Collisions in an Anisotropic Turbulent Flow; 4.4 Boundary Conditions for the Disperse Phase with the Consideration of Particle Collisions; 4.5 The Effect of Particle Collisions on Turbulent Stresses in a Homogeneous Shear Flow 4.6 The Effect of Collisions on Particle Motion in a Vertical Channel5 Relative Dispersion and Clustering of Monodispersed Particles in Homogeneous Turbulence; 5.1 The Kinetic Equation for the Two-Point PDF of Relative Velocity of a Particle Pair; 5.2 Equations for Two-Point Moments of Relative Velocity of a Particle Pair; 5.3 Statistical Properties of Stationary Suspension of Particles in Isotropic Turbulence; 5.4 Influence of Clustering on Particle Collision Frequency; 5.5 Relative Dispersion of Two Particles in Isotropic Turbulence; 5.5.1 Dispersion of Inertialess Particles 5.5.2 Dispersion of Inertial Particles |
| Record Nr. | UNINA-9910145450403321 |
|
Zaĭchik L. I (Leonid Isaakovich)
|
||
| Weinheim, : Wiley-VCH, c2008 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Particles in turbulent flows [[electronic resource] /] / Leonid Zaichik, Vladimir M. Alipchenkov, and Emmanuil G. Sinaiski
| Particles in turbulent flows [[electronic resource] /] / Leonid Zaichik, Vladimir M. Alipchenkov, and Emmanuil G. Sinaiski |
| Autore | Zaĭchik L. I (Leonid Isaakovich) |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | Weinheim, : Wiley-VCH, c2008 |
| Descrizione fisica | 1 online resource (319 p.) |
| Disciplina | 620.1064 |
| Altri autori (Persone) |
AlipchenkovVladimir M
SinaĭskiĭĖ. G (Ėmmanuil Genrikhovich) |
| Soggetto topico |
Particles - Statistical methods
Turbulence - Statistical methods |
| ISBN |
1-282-68870-7
9786612688706 3-527-62625-5 3-527-62626-3 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Particles in Turbulent Flows; Contents; Preface; Introduction; 1 Motion of Particles and Heat Exchange in Homogeneous Isotropic Turbulence; 1.1 Characteristics of Homogeneous Isotropic Turbulence; 1.2 Motion of a Single Particle and Heat Exchange; 1.3 Velocity and Temperature Correlations in a Fluid along the Inertial Particle Trajectories; 1.4 Velocity and Temperature Correlations for Particles in Stationary Isotropic Turbulence; 1.5 Particle Acceleration in Isotropic Turbulence; 2 Motion of Particles in Gradient Turbulent Flows
2.1 Kinetic Equation for the Single-Point PDF of Particle Velocity2.2 Equations for Single-Point Moments of Particle Velocity; 2.3 Algebraic Models of Turbulent Stresses; 2.3.1 Solution of the Kinetic Equation by the Chapman-Enskog Method; 2.3.2 Solution of the Equation for Turbulent Stresses by the Iteration Method; 2.4 Boundary Conditions for the Equations of Motion of the Disperse Phase; 2.5 Second Moments of Velocity Fluctuations in a Homogeneous Shear Flow; 2.6 Motion of Particles in the Near-Wall Region; 2.6.1 Near-Wall Region Including the Viscous Sublayer 2.6.2 The Equilibrium Logarithmic Layer2.6.3 High-Inertia Particles; 2.7 Motion of Particles in a Vertical Channel; 2.8 Deposition of Particles in a Vertical Channel; 3 Heat Exchange of Particles in Gradient Turbulent Flows; 3.1 The Kinetic Equation for the Joint PDF of Particle Velocity and Temperature; 3.2 The Equations for Single-Point Moments of Particle Temperature; 3.3 Algebraic Models of Turbulent Heat Fluxes; 3.3.1 Solution of the Kinetic Equation by the Chapman-Enskog Method; 3.3.2 Solving the Equation for Turbulent Heat Fluxes by the Iteration Method 3.4 Second Moments of Velocity and Temperature Fluctuations in a Homogeneous Shear Flow4 Collisions of Particles in a Turbulent Flow; 4.1 Collision Frequency of Monodispersed Particles in Isotropic Turbulence; 4.2 Collision Frequency in the Case of Combined Action of Turbulence and the Average Velocity Gradient; 4.3 Particle Collisions in an Anisotropic Turbulent Flow; 4.4 Boundary Conditions for the Disperse Phase with the Consideration of Particle Collisions; 4.5 The Effect of Particle Collisions on Turbulent Stresses in a Homogeneous Shear Flow 4.6 The Effect of Collisions on Particle Motion in a Vertical Channel5 Relative Dispersion and Clustering of Monodispersed Particles in Homogeneous Turbulence; 5.1 The Kinetic Equation for the Two-Point PDF of Relative Velocity of a Particle Pair; 5.2 Equations for Two-Point Moments of Relative Velocity of a Particle Pair; 5.3 Statistical Properties of Stationary Suspension of Particles in Isotropic Turbulence; 5.4 Influence of Clustering on Particle Collision Frequency; 5.5 Relative Dispersion of Two Particles in Isotropic Turbulence; 5.5.1 Dispersion of Inertialess Particles 5.5.2 Dispersion of Inertial Particles |
| Record Nr. | UNINA-9910829801603321 |
|
Zaĭchik L. I (Leonid Isaakovich)
|
||
| Weinheim, : Wiley-VCH, c2008 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Statistical approach in wall turbulence [[electronic resource] /] / Sedat Tardu
| Statistical approach in wall turbulence [[electronic resource] /] / Sedat Tardu |
| Autore | Tardu Sedat <1959-> |
| Pubbl/distr/stampa | London, : ISTE |
| Descrizione fisica | 1 online resource (326 p.) |
| Disciplina | 620.1/064 |
| Collana | ISTE |
| Soggetto topico |
Fluid-structure interaction - Statistical methods
Turbulence - Statistical methods Boundary value problems |
| ISBN |
1-118-60162-9
1-118-60158-0 1-118-60154-8 1-299-18757-9 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover; Statistical Approach to Wall Turbulence; Title Page; Copyright Page; Table of Contents; Foreword; Introduction; Chapter 1. Basic Concepts; 1.1. Introduction; 1.2. Fundamental equations; 1.2.1. Euler equations; 1.3. Notation; 1.4. Reynolds averaged Navier-Stokes equations; 1.5. Basic concepts of turbulent transport mechanisms; 1.5.1. Turbulent energy transport; 1.5.2. Inter-component transport; 1.6. Correlation tensor dynamics; 1.7. Homogeneous turbulence; 1.8. Isotropic homogeneous turbulence; 1.9. Axisymmetric homogeneous turbulence; 1.10. Turbulence scales; 1.11. Taylor hypothesis
1.12. Approaches to modeling wall turbulence 1.12.1. Direct numerical simulations; 1.12.2. Measurements; Chapter 2. Preliminary Concepts: Phenomenology, Closures and Fine Structure; 2.1. Introduction; 2.2. Hydrodynamic stability and origins of wall turbulence; 2.2.1. Linear stability; 2.2.2. Secondary stability, non-linearity and bypass transition; 2.3. Reynolds equations in internal turbulent flows; 2.4. Scales in turbulent wall flow; 2.5. Eddy viscosity closures; 2.6. Exact equations for fully developed channel flow; 2.6.1. Shear stress field; 2.6.2. Friction coefficient 2.6.3. "Laminar/turbulent" decomposition 2.7. Algebraic closures for the mixing length in internal flows; 2.8. Some illustrations using direct numerical simulations at low Reynolds numbers; 2.8.1. Turbulent intensities; 2.8.2. Fine structure; 2.8.3. Transport of turbulent kinetic energy and reformulation of the logarithmic sublayer; 2.8.4. Transport of the Reynolds shear stress -uv; 2.9. Transition to turbulence in a boundary layer on a flat plate; 2.10. Equations for the turbulent boundary layer; 2.11. Mean vorticity; 2.12. Integral equations; 2.13. Scales in a turbulent boundary layer 2.14. Power law distributions and simplified integral approach 2.15. Outer layer; 2.16. Izakson-Millikan-von Mises overlap; 2.17. Integral quantities; 2.18. Wake region; 2.19. Drag coefficient in external turbulent flows; 2.20. Asymptotic behavior close to the wall; 2.21. Coherent wall structures - a brief introduction; Chapter 3. Inner and Outer Scales: Spectral Behavior; 3.1. Introduction; 3.2. Townsend-Perry analysis in the fully-developed turbulent sublayer; 3.3. Spectral densities; 3.3.1. Longitudinal fluctuating velocity; 3.3.2. Spanwise fluctuating velocity 3.3.3. Fluctuating wall-normal velocity 3.3.4. Reynolds shear stress; 3.3.5. Summary: active and passive structures; 3.4. Clues to the Kx -1 behavior, and discussion; 3.5. Spectral density Ew and cospectral density Euv; 3.6. Two-dimensional spectral densities; Chapter 4. Reynolds Number-Based Effects; 4.1. Introduction; 4.2. The von Karman constant and the renormalization group; 4.2.1. Renormalization group (RNG); 4.2.2. The von Karman constant derived from the RNG; 4.3. Complete and incomplete similarity; 4.3.1. General considerations. Power law distributions 4.3.2. Implications for mixing length |
| Record Nr. | UNINA-9910138866703321 |
|
Tardu Sedat <1959->
|
||
| London, : ISTE | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Statistical approach in wall turbulence / / Sedat Tardu
| Statistical approach in wall turbulence / / Sedat Tardu |
| Autore | Tardu Sedat <1959-> |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | London, : ISTE |
| Descrizione fisica | 1 online resource (326 p.) |
| Disciplina | 620.1/064 |
| Collana | ISTE |
| Soggetto topico |
Fluid-structure interaction - Statistical methods
Turbulence - Statistical methods Boundary value problems |
| ISBN |
9781118601624
1118601629 9781118601587 1118601580 9781118601549 1118601548 9781299187573 1299187579 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover; Statistical Approach to Wall Turbulence; Title Page; Copyright Page; Table of Contents; Foreword; Introduction; Chapter 1. Basic Concepts; 1.1. Introduction; 1.2. Fundamental equations; 1.2.1. Euler equations; 1.3. Notation; 1.4. Reynolds averaged Navier-Stokes equations; 1.5. Basic concepts of turbulent transport mechanisms; 1.5.1. Turbulent energy transport; 1.5.2. Inter-component transport; 1.6. Correlation tensor dynamics; 1.7. Homogeneous turbulence; 1.8. Isotropic homogeneous turbulence; 1.9. Axisymmetric homogeneous turbulence; 1.10. Turbulence scales; 1.11. Taylor hypothesis
1.12. Approaches to modeling wall turbulence 1.12.1. Direct numerical simulations; 1.12.2. Measurements; Chapter 2. Preliminary Concepts: Phenomenology, Closures and Fine Structure; 2.1. Introduction; 2.2. Hydrodynamic stability and origins of wall turbulence; 2.2.1. Linear stability; 2.2.2. Secondary stability, non-linearity and bypass transition; 2.3. Reynolds equations in internal turbulent flows; 2.4. Scales in turbulent wall flow; 2.5. Eddy viscosity closures; 2.6. Exact equations for fully developed channel flow; 2.6.1. Shear stress field; 2.6.2. Friction coefficient 2.6.3. "Laminar/turbulent" decomposition 2.7. Algebraic closures for the mixing length in internal flows; 2.8. Some illustrations using direct numerical simulations at low Reynolds numbers; 2.8.1. Turbulent intensities; 2.8.2. Fine structure; 2.8.3. Transport of turbulent kinetic energy and reformulation of the logarithmic sublayer; 2.8.4. Transport of the Reynolds shear stress -uv; 2.9. Transition to turbulence in a boundary layer on a flat plate; 2.10. Equations for the turbulent boundary layer; 2.11. Mean vorticity; 2.12. Integral equations; 2.13. Scales in a turbulent boundary layer 2.14. Power law distributions and simplified integral approach 2.15. Outer layer; 2.16. Izakson-Millikan-von Mises overlap; 2.17. Integral quantities; 2.18. Wake region; 2.19. Drag coefficient in external turbulent flows; 2.20. Asymptotic behavior close to the wall; 2.21. Coherent wall structures - a brief introduction; Chapter 3. Inner and Outer Scales: Spectral Behavior; 3.1. Introduction; 3.2. Townsend-Perry analysis in the fully-developed turbulent sublayer; 3.3. Spectral densities; 3.3.1. Longitudinal fluctuating velocity; 3.3.2. Spanwise fluctuating velocity 3.3.3. Fluctuating wall-normal velocity 3.3.4. Reynolds shear stress; 3.3.5. Summary: active and passive structures; 3.4. Clues to the Kx -1 behavior, and discussion; 3.5. Spectral density Ew and cospectral density Euv; 3.6. Two-dimensional spectral densities; Chapter 4. Reynolds Number-Based Effects; 4.1. Introduction; 4.2. The von Karman constant and the renormalization group; 4.2.1. Renormalization group (RNG); 4.2.2. The von Karman constant derived from the RNG; 4.3. Complete and incomplete similarity; 4.3.1. General considerations. Power law distributions 4.3.2. Implications for mixing length |
| Record Nr. | UNINA-9910815239003321 |
|
Tardu Sedat <1959->
|
||
| London, : ISTE | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
