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Full Description
Volume 1:
The text comprehensively discusses the transport mechanism, storage, and conveying of the material, which are essential requirements for transporting solids in various process units, especially in mineral and chemical industries. It covers the properties of particles and particulate systems and focuses on their characterization and analysis.
This book:
Presents a discussion of theoretical principles coupled with illustrative examples to help readers learn how to operate, optimize, and innovate particle processing technologies.
Covers transport characterization of the solid-fluid operations, slurry physical properties, and properties of particles.
Illustrates systematic and comprehensive understanding of fundamental phenomena of properties of particles and handling of particulate systems.
Explains graphical representation of particle size, particle size measurement, and particle size distribution.
Includes ancillary material such as numerical problems, review questions, multiple choice questions, and exercises at the end of each chapter.
It is primarily written for senior undergraduates, graduate students, and academic researchers in fields including chemical engineering, mechanical engineering, environmental engineering, industrial engineering, manufacturing engineering, and chemistry.
Volume 2:
The text thoroughly discusses the fundamentals of flow resistance over a solid body, the frictional resistance of flow through a granular bed, and the flow phenomena of particles, which are essential requirements for solid-fluid operations in various process units, especially in mineral and chemical industries. It elucidates the fundamentals of drag force on a solid, terminal velocity of the particle, sedimentation, slurry mixing, fluidization phenomena, and froth flotation.
This book:
Presents a discussion of theoretical principles and illustrative examples to help readers learn how to operate, optimize, and innovate particle processing technologies.
Covers the fundamentals of drag force on a solid, terminal velocity of the particle, and sedimentation (hindered settling).
Explain the basic law and terminology of fluid flow through a granular bed, mixing characteristics in an agitator, and its standard design.
Illustrates systematic and comprehensive understandings of the fundamental phenomena of fluidization and the basic principles and kinetics of froth flotation.
Includes ancillary material such as numerical problems, review questions, multiple choice questions, and exercises at the end of each chapter.
It is primarily written for senior undergraduates, graduate students, and academic researchers in chemical engineering, mechanical engineering, environmental engineering, industrial engineering, manufacturing engineering, and chemistry.
Volume 3:
The text presents fundamental principles and analysis of the separation of particulate matter. Analysis and reduction of air pollution involve a variety of technical disciplines. The effective way to control air pollution is to prevent the release of pollutants at the source. The treatment can involve intimately contacting the effluent gases with liquids or solids capable of selectively removing gaseous pollutants or, in the case of particulate contaminants, directing the effluent flow through a device in which the particles are captured on surfaces.
This book:
Introduces the principle of separation methods of particulate matter (PM), common control equipment of PM, and collection or removal efficiency of the equipment.
Describes the concept of separation of particles by sieving/screening, the basic principles of screening equipment, and the screen's effectiveness.
Present the fundamental theories of removing particulate and gaseous pollutants from effluent streams by pollution control operations, such as gravitational (gravity chambers) and centrifugal deposition (cyclone separator), electrostatic precipitation, filtration, and wet scrubbing and covers fundamental principles of membrane separation, membrane modules, process design, applications, and governing equations of plate and frame filter press and rotary drum filter.
Deals with the basic understanding of reverse osmosis and its theoretical analysis by different total flux and capacity models and explains the basic understanding of adsorption onto the solid surface and their isotherm and kinetics.
Includes ancillary material such as numerical problems, review questions, multiple choice questions, and exercises at the end of each chapter.
It is primarily written for senior undergraduates, graduate students, and academic researchers in chemical engineering, mechanical engineering, environmental engineering, industrial engineering, manufacturing engineering, and chemistry.
Contents
Volume 1
Part 1. Introduction and Characteristics of Solids. 1. Introduction. 2. Single Particle Characterization. 3. Particle Size, Its Distribution, and Measurement in a Mixture. Part 2. Size Reduction of Solids. 4. Mechanism of Size Reduction. 5. General Machines for Size Reduction. 6. Energy for Size Reduction. Part 3. Size Enlargement 7. Introduction to Size Enlargement. 8. Mechanism of Size Enlargement. 9. Equipment for Size Enlargement. Part 4. Mixing of Solids. 10. Mixing of Solids. 11. Degree of Mixing and Its Assessment. Part 5. Transport and Storage of Solid. 12. Pneumatic Transport of Solid. 13. Transport by Conveyor and Elevator Systems. 14. Storage of Solid: Hopper.
Volume 2
Section 1. FLOW PAST CYLINDRICAL AND SPHERICAL PARTICLES. 1. The Drag Force on a Particle. 2. Terminal Velocity. 3. Sedimentation (Hindered Settling). Section 2. FLOW OF FLUID THROUGH A GRANULAR BED. 4. Basic Law and Terminology of Flow of Fluid through a Granular Bed. 5. General Expressions for Flow of Fluid through Packed Beds. 6. Two-phase Flow in Packed Bed. 7. Mixing of Fluids with Solids. Section 3. FLUIDIZATION OF PARTICLES. 8. Basic Understandings and Applications of Fluidization. 9. Minimum Fluidization Velocity. 10. Minimum Fluidization Velocity with Mixture of Particles. Section 4. FROTH FLOTATION. 11. Basics of Froth Flotation. 12. Flotation Kinetics.
Volume 3
1. Principle of Separation of Particles. 2. Separation of Particles by Sieving/Screening. 3. Separation by Gravity Chambers, Granular bed and Elutriation. 4. Separation of Particles by Cyclone Separator. 5. Separation of Particles by Electrostatic Precipitator. 6. Separation of Particles by Industrial Fabric (Bag) Filters. 7. Separation of Particulate Matters by Wet Scrubbers. 8. Separation by Membrane Filtration: Introduction. 9. Separation by Dead-End and Continuous Filtration. 10. Osmosis and Reverse Osmosis. 11. Separation by Adsorption: Principles and Applications. 12. Adsorption Isotherms. 13. Kinetics of Adsorption.
