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IUTAM Symposium on Computational Approaches to Multiphase Flow Proceedings of an IUTAM Symposium held at Argonne National Laboratory, October 4-7, 2004 /
| Clasificación: | Libro Electrónico |
|---|---|
| Autor Corporativo: | |
| Otros Autores: | , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Dordrecht :
Springer Netherlands : Imprint: Springer,
2006.
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| Edición: | 1st ed. 2006. |
| Colección: | Fluid Mechanics and Its Applications,
81 |
| Temas: | |
| Acceso en línea: | Texto Completo |
Tabla de Contenidos:
- Point Particle Approach
- An Updated Classification Map of Particle-Laden Turbulent Flows
- On Fluid-Particle and Particle-Particle Interactons in Gas-Solid Turbulent Channel Flow
- Simulation of Particle Diffusion, Segregation, and Intermittency in Turbulent Flows
- Use of a Stochastic Method to Describe Dispersion and Deposition in an Idealized Annular Flow
- On Momentum Coupling Methods for Calculation of Turbulence Attenuation in Dilute Particle-Laden Gas Flows
- Multifractal Concentrations of Heavy Particles in Random Flows
- Turbulence Modulation by Micro-Particles in Boundary Layers
- Stochastic Diffusion of Finite Inertia Particles in Non-Homogeneous Turbulence
- Accumulation of Heavy Particles in Bounded Vortex Flow
- Lattice-Boltzmann and Molecular Dynamic Simulations
- A Numerical Study of Planar Wave Instabilities in Liquid-Fluidized Beds
- Lattice Boltzmann Simulations to Determine Forces Acting on Non-Spherical Particles
- Molecular Dynamics Simulations of Drop Motion on Uniform and Non-Uniform Solid Surfaces
- Fluctuating Immersed Material (FIMAT) Dynamics for the Direct Simulation of the Brownian Motion of Particles
- A Novel Definition of the Local and Instantaneous Liquid-Vapor Interface
- Fully-Resolved Multi-Particle Simulations
- DNS of Collective Behavior of Solid Particles in a Homogeneous Field
- Proteus-A New Computational Scheme for Deformable Particles and Particle Interaction Problems
- An Explicit Finite-Difference Scheme for Simulation of Moving Particles
- Use of Variable-Density Flow Solvers for Fictitious-Domain Computations of Dispersed Solid Particles in Liquid Flow
- 3D Unsteady Simulation of Particle Sedimentation towards High Regimes
- Microstructural Effects in a Fully-Resolved Simulation of 1,024 Sedimenting Spheres
- A DNS Approach Dedicated to the Analysis of Fluidized Beds
- Performance of Various Fluid-Solid Coupling Methods for DNS of Particulate Flow
- Numerical Study of Particle Migration in Tube and Plane Poiseuille Flows
- New Advances in Force-Coupling Method: From Micro to Macro
- Treatment of Particle Collisions in Direct Numerical Simulations of High Speed Compressible Flows
- Free Surface Flows, Drops and Bubbles
- Struggling with Boundary Layers and Wakes of High-Reynolds-Number Bubbles
- Direct Numerical Simulations of Bubbly Flows
- Direct Numerical Simulation of Droplet Formation and Breakup
- A Sharp-Interface Cartesian Grid Method for Computations of Droplet Impact and Spreading on Surfaces of Arbitrary Shape
- A Finite-Volume/Front-TrackingMethod for Computations of Multiphase Flows in Complex Geometries
- The Effect of Surfactant on Rising Bubbles
- Numerical Simulation of Shock Propagation in Bubbly Liquids by the Front Tracking Method
- Large-Eddy Simulation of Steep Water Waves
- Adaptive Characteristics-Based Matching (aCBM): A Method for Interfacial Dynamics in Compressible Multiphase Flows
- Compressible Multi-Hydrodynamics (CMH): Breakup, Mixing, and Dispersal of Liquids/Solids in High Speed Flows
- Large Eddy Simulations, Applications and Other Physics
- On Stochastic Modeling of Heavy Particle Dispersion in Large-Eddy Simulation of Two-Phase Turbulent Flow
- Flow of Bubbly Liquids in a Vertical Pipe: Theory and Experiments
- Effect of Particle Inertia in Particulate Density Currents
- Modeling Finite-Size Effects in LES/DNS of Two-Phase Flows
- Lagrangian Aspects to Multiphase Flows
- Effect of Fluid Velocity Fluctuations on the Dynamics of a Sheared Gas-Particle Suspension
- Prediction of Particle Laden Turbulent Channel Flow Using One-Dimensional Turbulence.