Bridging scales in modelling and simulation of non-reacting and reacting flows. Part 2 /
Bridging Scales in Modelling and Simulation of Reacting Flows, Part B, Volume 53, presents key methods used to bridge scales in the simulation of reacting multiphase flows. It looks at the different aspects of such flows (transport phenomena, reactions) and includes illustrations of the methods on a...
Άλλοι συγγραφείς: | , |
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Μορφή: | Ηλ. βιβλίο |
Γλώσσα: | English |
Έκδοση: |
Cambridge, MA :
Academic Press,
2018.
|
Έκδοση: | First edition. |
Σειρά: | Advances in chemical engineering ;
v. 53. |
Θέματα: | |
Διαθέσιμο Online: | Full Text via HEAL-Link Full Text via HEAL-Link |
Πίνακας περιεχομένων:
- Front Cover; Bridging Scales in Modelling and Simulation of Non-Reacting and Reacting Flows. Part II; Copyright; Contents; Contributors; Preface; Chapter One: Multiscale Modelling of Dense Gas-Particle Flows; 1. Introduction; 2. DNS; 2.1. Governing Equations DNS; 2.1.1. Fluid Phase Equations; 2.1.2. Particle Equations; 2.2. Numerical Solution Method DNS; 2.3. Results DNS; 2.3.1. Flow and Heat Transfer in Stationary Particle Arrays; 2.3.2. Fluidization of Spheres in a Pseudo 2D Bed; 3. DEM; 3.1. Governing Equations DEM; 3.1.1. Fluid Phase Equations; 3.1.2. Particle phase equations
- 3.2. Numerical Solution Method DEM3.3. Results DEM; 3.3.1. Gas-Fluidized Beds With Heat Production; 3.3.2. Hydrodynamics of a Pseudo 2D Riser; 4. TFM; 4.1. Governing Equations TFM; 4.2. Numerical Solution Method TFM; 4.3. Results TFM; 4.3.1. Hydrodynamics of a Pseudo 2D Gas-Fluidized Bed; 4.3.2. Hydrodynamics of a 3D Cylindrical Bed; 4.3.3. Gas-Fluidized Bed With Heat Production; 5. Conclusions and Outlook; Acknowledgments; References; Chapter Two: Advances in Coarse Discrete Particle Methods With Industrial Applications; 1. Introduction
- 2. Description of Methods for Solving Fluid-Particle Flow2.1. Computational Fluid Dynamics Coupled With Soft-Sphere Contact Model; 2.1.1. Fluid Dynamics; 2.1.2. Momentum Transfer Models; 2.1.3. Solid Particle Dynamics; 2.1.4. Heat Transfer Model; 2.1.5. Species Transport With Chemical Reactions; 2.2. Coarse-Grained Soft-Sphere Contact Model; 2.2.1. Basic Assumptions in Coarse-Grained Soft-Sphere Contact Model; 2.2.2. Recent Advances in Coarse-Grained Soft-Sphere Contact Model; 2.2.3. Extension to Heat Transfer; 2.3. Extension to Time-Driven Hard-Sphere Contact Model
- 3. Verification and Validation Studies3.1. Verification Study of the Time-Driven Hard Sphere Model for Dense Granular Flow; 3.2. Validation of Time-Driven Hard Sphere Model for Bubbling Fluidized Bed; 3.3. Verification Study of Coarse-Grained Soft-Sphere and Hard-Sphere Contact Models; 3.4. Validation of Heat Transfer in Coarse-Grained Soft-Sphere Contact Model; 3.5. Validation of Coarse-Grained Hard-Sphere Model for Pilot-Scale CFB Riser; 4. Application of Coarse-Grained Hard Sphere Method to Industrial Reactors; 4.1. Simulation of a Fluidized Catalytic Cracking Regenerator
- 4.1.1. Simulation Setup4.1.2. Chemical Reaction Kinetics Model; 4.1.3. Results and Discussion; 4.1.3.1. Hydrodynamics of Fluidized Particles in the Regenerator; 4.1.3.2. Temperature Profiles and Heat Transfer; 4.1.3.3. Species Concentration in the Regenerator; 4.2. Simulation of a Methanol to Olefins Reactor; 4.2.1. Simulation Setup; 4.2.2. Chemical Reaction Kinetics Model; 4.2.3. Results and Discussion; 4.3. Simulation of a Rare Earth Elements Leaching Reactor; 4.3.1. Validation of Chemical Reactions; 4.3.2. Simulation of a Small Counter-Current Reactor Under Different Operating Conditions