Amsterdam, : Elsevier, 2008

1-281-05981-1

9786611059811

0-08-055341-9

1 online resource (535 p.)

UF 4000

HelvacSerife S

YenerBanu

IkizlerBerrin

AlparslanAlp

532.051

Solid-liquid interfaces

Two-phase flow

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Front cover; Solid-Liquid Two Phase Flow; Copyright page; Preface; Contents; List of Contributors; Chapter 1. The Particulate Phase: A Voyage from the Molecule to the Granule; 1.1 Molecular Interactions; 1.2 Interactions of Electrical Origin Between Particles; 1.3 Interaction of Particles Due to Non-Dlvo Forces; 1.4 Aggregation of Particles; 1.5 Aggregation of Ferromagnetic Particles; 1.6 Formation of Glasses and Gels; 1.7 Self-Assemblies of Surfactants; 1.8 Stabilization of Suspensions; 1.9 Aggregation in Biological Systems; Chapter 2. Non-Newtonian Behavior of Solid-Liquid Suspensions

2.1 Viscoelasticity2.2 Rheological Models of Time-Independent Non-Newtonian Fluids; 2.3 Flow of Non-Newtonian Fluids Through Cylindrical Pipes; 2.4 Flow Through Noncylindrical Channels; Chapter 3. Concentrated Suspensions; 3.1 Ordering in Concentrated Suspensions; 3.2 Rheology of Concentrated Hard-Sphere Suspensions; 3.3 Rheology of Soft-Particle Suspensions; 3.4 Migration, Slip, and Drag Reduction; 3.5 Shear Flow of Viscoelastic Suspensions; 3.6 Flow of Biological Fluids: Blood Flow in the Circulatory System; Chapter 4. Motion of

Particles in Fluids; 4.1 Motion of the Fluid Phase

4.2 Forces Acting on Particles4.3 Motion of Spherical Particles; 4.4 Motion of Nonuniform Particles; 4.5 Hindered Settling; Chapter 5. Modeling the Flow of Settling Suspensions; 5.1 Basic Concepts in Modeling of Two-Phase Flow; 5.2 Averaging Techniques for Model Equations; 5.3 Mathematical Requirements for Averaging Transport Equations; 5.4 Basic Equations for Solid-Liquid Suspension Flows; 5.5 Ensemble Averaged Equations for Two-Fluid Model; 5.6 Eulerian Single Fluid Model: Mixture Model; 5.7 Mixture Model on Macroscale: General Balance Equations; 5.8 Drift Flux Model

Chapter 6. Flow of Settling Slurries6.1 Flow Patterns and Flow Regimes; 6.2 General Balance Equations for Flow of Slurries Through Pipes; 6.3 Dispersion Mechanisms of Solid Particles; 6.4 Mechanism of Frictional Losses; 6.5 Pressure Losses in Pipe Flow; 6.6 Particle Concentration Distributions in Different Flow Patterns; 6.7 Deposition Velocity; 6.8 Settling Flow of Solid-Liquid Suspensions with Stationary Bed; Chapter 7. Mixing in Solid-Liquid Systems; 7.1 The Role of Surface Tension in Wetting of Solids; 7.2 Discharge of Solids into Liquids; 7.3 Mechanisms of Mixing

7.4 Mechanically Agitated Mixers7.5 Static Mixers; 7.6 Mixing of Concentrated Suspensions; 7.7 Mixing in the Microscale; Chapter 8. Classification and Separation of Solid-Liquid Systems; 8.1 Classification and Separation in a Gravitational Field; 8.2 Separation in a Magnetic Field; 8.3 Separations in the Microscale; Appendix A. Mathematical Operations; Appendix B. Population Balances; Appendix C. Tables for Use in Plug Flow in an Annulus; Index

This book is an undertaking of a pioneering work of uniting three vast fields of interfacial phenomena, rheology and fluid mechanics within the framework of solid-liquid two phase flow.  No wonder, much finer books will be written in the future as the visionary aims of many nations in combining molecular chemistry, biology, transport and interfacial phenomena for the fundamental understanding of processes and capabilities of new materials will be achieved.  Solid-liquid systems where solid particles with a wide range of physical properties, sizes ranging from nano- to macro- scale and concentr