Chapter 1 THE FLUIDIZED STATE

 1.1 The Fluidized State and How It Is Achieved

 1.2 Nature of Hydrodynamic Suspension

 1.3 Particle-Particle Forces

 1.4 Species of Fluidization

 1.5 Regimization of the Fluidized State

Chapter 2 IDEALIZATION OF THE FLUIDIZING PROCESS: Empnal Deductions from L/S Systems

Chapter 3 GENERALIZED FLUIDIZATION

 3.1 Steady-State Motion

 3.2 Moving Bed

 3.3 Accelerative Motion

 3.4 Polydisperse Systems

 3.5 Computer Software

Chapter 4 FLUIDIZED LEACHING AND WASHING

 4.1 Characteristics

 4.2 Uniform Particles

 4.3 Mixed Particles

 4.4 Experimental Findings

 4.5 Staging

 4.6 Rate Measurement for Solids Leaching and Washing

Chapter 5 SOLIDS MIXING AND SEGREGATION

 5.1 Phase Juxtaposition

 5.2 Operation ShiRs

 5.3 Reversal Points

 5.4 Degree of Segregation

 5.5 Mixing-Segregation Equilibrium

 5.6 Generalized Fluidization of Polydisperse Systems

Chapter 6 CONICAL FLUIDIZED BEDS

 6.1 Phenomenological Description and Physical Modeling

 6.2 The Basic Parameters

 6.3 The Fully Fluidized State

 6.4 With Hyperfluidized Fixed Bed

 6.5 Ranges for Conical Fluidized Bed Operation

 6.6 Charting Conical Fluidized Bed Operation and Experimental Verification

 6.7 Instability

Chapter 7 APPLICATION OF THE MOVING BED

 7.1 Moving Bed Uptransport with Compressible Media

 7.2 The Pneumatically Controlled Downcomer

Chapter 8 BUBBLELESS GAS/SOLID CONTACTING

 8.1 Bubbling Fluidization and G/S Contacting Efficiency

 8.2 Species of Bubbleless G/S Contacting

Chapter 9 SYSTEMS WITH DILUTE RAINING PARTICLES

 9.1 Raining-Particles Heat Exchanger

 9.2 Polydisperse Particles

 9.3 Experimental Verification

 9.4 Baffling and Particles Distribution

 9.5 Countercurrent Staging of Cocurrent Systems

 9.6 Pilot Plant Demonstration i

Chapter 10 VOIDAGE DISTRIBUTION IN FAST FLUIDIZATION

 10.1 Modeling Longitudinal Voidage Distribution

 10.2 Evaluation of Parameters

 10.3 Computing Voidage Distribution

 10.4 Regime Diagram

 10.5 Generalized Fluidization of Nonideal Systems

 10.6 Radial Voidage Distribution

Chapter 11 SHALLOW FLUIDIZED BED

 11.1 Relevant Work on Distributor

 11.2 Fluid Flow above Distributor

 11.3 Particle Behavior above Distributor

 11.4 Assessment of Distributor Performance

 11.5 Particle-Gas Transfer in Shallow Fluid Bed

 11.6 Activated Solids Shallow Fluid Bed Heat Exchanger

 11.7 Cocurrent Multi-Stage Shallow Fluid Bed

 11.8 The co-MSFB as a Chemical Reactor

Chapter 12 FLUIDIZATION WITH NO NET FLUID FLOW

 12.1 Levitation of Discrete Particles

 12.2 Semi-Fluidization through Oscillatory Flow

 12.3 Application to Pseudo Solid-Solid Reaction

Chapter 13 A COHERENT ANALYSIS FOR L/S AND G/S SYSTEMS

 13.1 From Phenomena through Hypothesis to Modeling

 13.2 The Multi-Scale Energy-Minimization Model

 13.3 Charting Status Parameters

 13.4 Reconciling L/S and G/S Systems

 13.5 Regimes of Fluidization

Chapter 14 POWDER ASSESSMENT

 14.1 Geldart's Classification

 14.2 Powder Characterization by Bed Collapsing

 14.3 Modeling the Three-Stage Bed Collapsing Process

 14.4 Instrument for Automatic Surface Tracking and Data Processing

 14.5 Qualitative Designation for Bed Collapsing

 14.6 Quantifying Fluidizing Characteristics of Powders

 14.7 Improving Fluidization by Particle Size Adjustment

 14.8 Fluidizing Quality and Particle-Particle Interaction

 14.9 Measure of Synergism for Binary Particle Mixtures

Chapter 15 FUTURE PROSPECTS

 15.1 Basic Mechanism

 15.2 Further Reconciliation between G/S and L/S Systems

 15.3 Polydisperse Systems and Powder Design

 15.4 Intensification of L/S Operations

 15.5 Staged Operation

 15.6 Existing and New L/S Processes

 15.7 Examples of Opportunities for Bubbleless G/S Contacting

NOTATIONS

References

SUBJECT INDEX

 ADDENDA

Chapter 16 FAST FLUIDIZATION AND ITS APPLICATIONS

 16.1 Types of Fast Fluidized Bed

 16.2 Gas-solid Flow in Riser

 16.3 Gas-solid Flow in Downcomer

 16.4 Applications of Fast Fluidization

 References

Chapter 17 MAGNETOFLUIDIZATION

 17.1 Types of Magnetofluidized Bed

 17.2 Structure of Magnetofluidized Bed

 17.3 Hydrodynamics of Magnetofluidization

 17.4 Mixing Behaviors

 17.5 Mass and Heat Transfer

 17.6 Applications of Magnetofluidization

References

When fluidization was first employed industrially,e.g., in the Winkler gasifier, we had only the bubbling fluidized bed as shown in the middle diagram of the figure, in which gas bypasses as bubbles, thus leading to poor solid-gas contact and incurring large pressure drop. What is ideal is the high dispersion of solids shown as the background of the book jacket. Short of such an ideal state, we may resort to suppressing bubbles by the use of shallow fluidized bed as shown on the lefthand side diagram achieved through reducing the solid content of the fluidized bed, or the fast fluidized bed with continuous recycling of solids to the bottom of the bed, as shown on the righthand side diagram. All these diagrams of fluidization were generated through computer modeling by Professor Wei Ge, and from hosts of these diagrams, four were selected by Xue Bai,Jianxing Lu and Ying Ren to portray the principal thesis of this book.

What is ideal is the high dispersion of solids shown as the background of the book jacket. Short of such an ideal state, we may resort to suppressing bubbles by the use of shallow fluidized bed as shown on the lefthand side diagram achieved through reducing the solid content of the fluidized bed, or the fast fluidized bed with continuous recycling of solids to the bottom of the bed, as shown on the righthand side diagram.