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Impinging-stream reactors : fundamentals and applications /
Impinging streams is a unique and multipurpose configuration of a two-phase suspension for intensifying transfer processes in heterogeneous systems, viz. gas-solid, gas-liquid, solid-liquid and liquid-liquid. The essence of the method lies in the collision which results from bringing two streams of...
| Clasificación: | Libro Electrónico |
|---|---|
| Autor principal: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Amsterdam ; New York :
Elsevier,
1994.
|
| Colección: | Transport processes in engineering ;
7. |
| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Front Cover; Impinging-Stream Reactors: Fundamentals and Applications; Copyright Page; PREFACE; ACKNOWLEDGMENTS; Table of Contents; Chapter 0. Impinging streams
- a humorous introduction; Essence; Origin; Artistic demonstrations; Concluding remarks; Chapter 1. Why write this book?; Chapter 2. Analysis of process improvement and origin of impinging streams; 2.1 Efficiency indices of transfer processes; 2.2 Processes improvement based on the thermodynamics of irreversible processes; 2.3 Characteristics of impinging streams; 2.4 Verification of intensification effects in impinging streams.
- NomenclatureChapter 3. Classification and configurations of impinging-stream reactors; NOMENCLATURE; Chapter 4. Single-phase impinging streams; 4.1 Flow visualization and its characteristics; 4.2 Velocity field in laminar impinging streams; 4.3 Velocity distribution in impinging streams-experimental results; 4.4 Turbulent impinging streams; 4.5 Applications of single-phase impinging streams; Nomenclature; Chapter 5. The behavior of a single particle; 5.1 Motion of a single particle in the absence of a gravitational force.
- 5.2 Investigations of motion of a particle in the absence of a gravitational force5.3 motion of a single particle in the presence of a gravitational force; 5.4 Design considerations; Nomenclature; Chapter 6. The behavior of a multiparticle system; 6.1 Experimental observations; 6.2 The effect of particle concentration; 6.3 The effect of interparticle collisions; 6.4 Markov-chain analysis of particle behavior in gas-solid suspensions; 6.5 Analysis of particle behavior in solid-liquid suspensions; Nomenclature; Chapter 7. Heat transfer and drying; 7.1 Modeling of heat transfer enhancement.
- 7.2 Models for heat transfer to a particle7.3 Heat transfer characteristics of impinging-stream dryers; 7.4 Industrial applications of ISD; 7.5 Measurement of heat transfer coefficients; 7.6 Design considerations for impinging streams; Nomenclature; Chapter 8. Combustion processes; 8.1 Basic flow configurations; 8.2 Combustion of gas; 8.3 Combustion of droplets and particles; 8.4 Practical impinging-stream combustors; Nomenclature; Chapter 9. Solid-liquid processes; 9.1 Dissolution of solids; 9.2 Ion exchange; 9.3 Electrochemical mass transfer; Nomenclature; Chapter 10. Solid-gas processes.
- 10.1 Mixing10.2 Size reduction and classification; 10.3 Enrichment of phosphate; 10.4 Production of solid pigments; 10.5 Milling-roasting-reduction of iron oxide depleted ores; 10.6 Plasma-jet processes; 10.7 Dust collection and granulation; Nomenclature; Chapter 11. Liquid-gas processes; 11.1 Absorption and desorption of gases; 11.2 Evaporative cooling of air; Nomenclature; Chapter 12. Liquid-liquid processes; 12.1 Extraction; 12.2 Creation of emulsions by impinging streams; Nomenclature.