Design of multiphase reactors /
"This resource offers a primer on simple design methods for multiphase reactors in the chemical process industries, particularly the fine chemicals industry. It provides the process design engineer with simple yet theoretically sound procedures. Different types of multiphase reactors are dealt...
| Κύριος συγγραφέας: | |
|---|---|
| Μορφή: | Ηλ. βιβλίο |
| Γλώσσα: | English |
| Έκδοση: |
Hoboken, New Jersey :
Wiley,
2014.
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| Θέματα: | |
| Διαθέσιμο Online: | Full Text via HEAL-Link |
Πίνακας περιεχομένων:
- Title page; Copyright page; Dedication; Foreword; Preface; References; 1 Evolution of the Chemical Industry and Importance of Multiphase Reactors; 1.1 Evolution of Chemical Process Industries; 1.2 Sustainable and Green Processing Requirements in the Modern Chemical Industry; 1.3 Catalysis; 1.4 Parameters Concerning Catalyst Effectiveness in Industrial Operations; 1.5 Importance of Advanced Instrumental Techniques in Understanding Catalytic Phenomena; 1.6 Role of Nanotechnology in Catalysis; 1.7 Click Chemistry; 1.8 Role of Multiphase Reactors; References
- 2 Multiphase Reactors: The Design and Scale-Up Problem2.1 Introduction; 2.2 The Scale-Up Conundrum; 2.3 Intrinsic Kinetics: Invariance with Respect to Type/Size of Multiphase Reactor; 2.4 Transport Processes: Dependence on Type/Size of Multiphase Reactor; 2.5 Prediction of the Rate-Controlling Step in the Industrial Reactor; 2.6 Laboratory Methods for Discerning Intrinsic Kinetics of Multiphase Reactions; Nomenclature; References; 3 Multiphase Reactors: Types and Criteria for Selection for a Given Application; 3.1 Introduction to Simplified Design Philosophy
- 3.2 Classification of Multiphase Reactors3.3 Criteria for Reactor Selection; 3.4 Some Examples of Large-Scale Applications of Multiphase Reactors; Nomenclature; References; 4 Turbulence: Fundamentals and Relevance to Multiphase Reactors; 4.1 Introduction; 4.2 Fluid Turbulence; Nomenclature; References; 5 Principles of Similarity and Their Application for Scale-Up of Multiphase Reactors; 5.1 Introduction to Principles of Similarity and a Historic Perspective; 5.2 States of Similarity of Relevance to Chemical Process Equipments; Nomenclature; References
- 6 Mass Transfer in Multiphase Reactors: Some Theoretical Considerations6.1 Introduction; 6.2 Purely Empirical Correlations Using Operating Parameters and Physical Properties; 6.3 Correlations Based on Mechanical Similarity; 6.4 Correlations Based on Hydrodynamic/Turbulence Regime Similarity; Nomenclature; References; 7A Stirred Tank Reactors for Chemical Reactions; 7A.1 Introduction; 7A.2 Power Requirements of Different Impellers; 7A.3 Hydrodynamic Regimes in Two-Phase (Gas-Liquid) Stirred Tank Reactors; 7A.4 Hydrodynamic Regimes in Three-Phase (Gas-Liquid-Solid) Stirred Tank Reactors
- 7A.5 Gas Holdup in Stirred Tank Reactors7A.6 Gas-Liquid Mass Transfer Coefficient in Stirred Tank Reactor; 7A.7 Solid-Liquid Mass Transfer Coefficient in Stirred Tank Reactor; 7A.8 Design of Stirred Tank Reactors with Internal Cooling Coils; 7A.9 Stirred Tank Reactor with Internal Draft Tube; 7A.10 Worked Example: Design of Stirred Reactor for Hydrogenation of Aniline to Cyclohexylamine (Capacity: 25,000 Metric Tonnes per Year); Nomenclature; References; 7B Stirred Tank Reactors for Cell Culture Technology; 7B.1 Introduction; 7B.2 The Biopharmaceutical Process and Cell Culture Engineering
