Rhodes | Introduction to Particle Technology 2e | Buch | 978-0-470-01427-1 | sack.de

Buch, Englisch, 472 Seiten, Format (B × H): 175 mm x 250 mm, Gewicht: 992 g

Rhodes

Introduction to Particle Technology 2e


Buch, Englisch, 472 Seiten, Format (B × H): 175 mm x 250 mm, Gewicht: 992 g

ISBN: 978-0-470-01427-1
Verlag: Wiley

In general terms, microstructural characterization is achieved by allowing some form of probe to interact with a carefully prepared specimen sample. The most commonly used probes are visible light, X-ray radiation and high-energy electron beams. These three types of probe form the basis for optical microscopy, X-ray diffraction and electron microscopy.

The book is an introduction to the expertise involved in assessing the microstructure of engineering materials and to the experimental methods used for this purpose. In the same way as the first edition, Microstructural Characterization of Materials - 2nd edition will explore the methodology of materials characterization under the three headings of crystal structure, microstructural morphology, and microanalysis. The principal methods of characterization including diffraction analysis, optical microscopy, electron microscopy, and chemical microanalytical techniques are treated in full. An additional chapter has been added to the new edition on surface probe microscopy and there are new sections on digital recording, processing, and analysis. The second edition has been updated, and has revised and expanded problems from the first edition to aid learning.

The book will appeal to senior undergraduate and graduate students of material sciences, materials engineering and materials chemistry. In addition, more advanced researchers will find the book useful as a general reference source.
Rhodes Introduction to Particle Technology 2e jetzt bestellen!

Autoren/Hrsg.

Rhodes, Martin J
Rhodes, Martin

Fachgebiete

Weitere Infos & Material

1.Particle Size Analysis

1.1Introduction

1.2 Describing The Size Of A Single Particle

1.3 Description Of Populations Of Particles

1.4 Conversion Between Distributions

1.5 Describing The Population By A Single Number

1.6 Equivalence Of Means

1.7 Common Methods Of Displaying Size Distributions

1.8 Methods Of Particle Size Measurement

1.9 Sampling

1.10 Worked Examples

Exercises

2. Single Particles in a Fluid

2.1 Motion Of Solid Particles In A Fluid

2.2 Particles Falling Under Gravity Through A Fluid

2.3 Non-Spherical Particles

2.4 Effect Of Boundaries On Terminal Velocity

2.5 Further Reading

2.6 Worked Examples

Exercises

3. Multiple Particle Systems

3.1 Settling Of A Suspension Of Particles

3.2 Batch Settling

3.3 Continuous Settling

3.4 Worked Examples

Exercises

4. Slurry Transport

4.1 Introduction

4.2 Flow Condition

4.3 Rheological Models For Homogeneous Slurries

4.4 Heterogeneous Slurries

4.5 Components Of A Slurry Flow System

4.6 Worked Examples

4.7 Further Reading

Exercises

References

5. Colloids and Fine Particles

5.1 Introduction

5.2 Brownian Motion

5.3 Surface Forces

5.4 Result of Surface Forces on Behaviour in Air and Water.

5.5 Influences of Particle Size and Surface Forces on Solid/Liquid Separation by Sedimentation

5.6 Suspension Rheology

5.7 Influence of Surface Forces on Suspension Flow

5.8 Nanoparticles

5.9 Worked Examples

Exercises

References

6. Fluid Flow Through a Packed Bed of Particles

6.1 Pressure Drop-Flow Relationship

6.2 Filtration

6.3 Further Reading

6.4 Worked Examples

Exercises

7. Fluidization

7.1 Fundamentals

7.2 Relevant Powder And Particle Properties

7.3 Bubbling And Non-Bubbling Fluidization

7.4 Classification Of Powders

7.5 Expansion Of A Fluidized Bed

7.6 Entrainment

7.7 Heat Transfer In Fluidized Beds

7.8 Applications Of Fluidized Beds

7.9 A Simple Model For The Bubbling Fluidized Bed Reactor

7.10 Some Practical Considerations

7.11 Worked Examples

Exercises

8. Pneumatic transport and standpipes

8.1 Pneumatic Transport

8.2 Standpipes

8.3 Further Reading

8.4 Worked Examples

Exercises

9. Separation of Particles

9.1 Gas Cyclones - Description

9.2 Flow Characteristics

9.3 Efficiency Of Separation

9.4 Scale-Up Of Cyclones

9.5 Range Of Operation

9.6 Some Practical Design And Operation Details

9.7 Worked Examples

Exercises

10. Storage and Flow of Powders - Hopper Design

10.1 Introduction

10.2 Mass Flow And Core Flow

10.3 The Design Philosophy

10.4 Shear Cell Tests

10.5 Analysis Of Shear Cell Test Results

10.6 Summary Of Design Procedure

10.7 Discharge Aids

10.8 Pressure On The Base Of A Tall Cylindrical Bin

10.9 Mass Flow Rates

10.10 Conclusions

10.11 Worked Examples

Exercises

11. Mixing and Segregation

11.1 Introduction

11.2 Types Of Mixture

11.3 Segregation

11.4 Reduction Of Segregation

11.5 Equipment For Particulate Mixing

11.6 Assessing The Mixture

11.7 Worked Examples

Exercises

12. Particle Size Reduction

12.1 Introduction

12.2 Particle Fracture Mechanisms

12.3 Model Predicting Energy Requirement And Product Size Distribution

12.4 Types Of Comminution Equipment

12.5 Worked Examples

Exercises

13. Size Enlargement

13.1 Introduction

13.2 Interparticle Forces

13.3 Granulation

13.4 Worked Examples

Exercises

Notation

14. Health effects of fine powders

14.1 Introduction

14.2 The human respiratory system

14.3 Interaction of fine powders with the respiratory system

14.4 Pulmonary delivery of drugs

14.5 Harmful effects of fine powders

References

Exercises

15. Fire and Explosion Hazards of Fine Powders

15.1 Introduction

15.2 Combustion Fundamentals

15.3 Combustion In Dust Clouds

15.4 Control Of The Hazard

15.5 Worked Examples

Exercises

16. Case Studies

List of Symbols

References

Notation

References Index

Martin Rhodes holds a Bachelor's degree in chemical engineering and a PhD in particle technology from Bradford University in the UK, industrial experience in chemical and combustion engineering and many years experience as an academic at Bradford and Monash Universities. He has research interests in various aspects of gas fluidization and particle technology, areas in which he has many refereed publications in journals and international conference proceedings. Martin is on the editorial board of Advanced Powder technology. Martin has a keen interest in particle technology education and has published books and CDROM on Laboratory demonstrations and directed continuing education courses for industry in the UK and Australia. He was co-founder of the Australasian Particle Technology Society. Martin has a Personal chair in the Department of Chemical Engineering at Monash University, Australia, where he is presently Head of Department.

Ihre Fragen, Wünsche oder Anmerkungen
Vorname*
Nachname*
Ihre E-Mail-Adresse*
Kundennr.
Ihre Nachricht*
Lediglich mit * gekennzeichnete Felder sind Pflichtfelder.
Wenn Sie die im Kontaktformular eingegebenen Daten durch Klick auf den nachfolgenden Button übersenden, erklären Sie sich damit einverstanden, dass wir Ihr Angaben für die Beantwortung Ihrer Anfrage verwenden. Selbstverständlich werden Ihre Daten vertraulich behandelt und nicht an Dritte weitergegeben. Sie können der Verwendung Ihrer Daten jederzeit widersprechen. Das Datenhandling bei Sack Fachmedien erklären wir Ihnen in unserer Datenschutzerklärung.