Pervaporation, vapour permeation and membrane distillation : principles and applications

Vapour permeation and membrane distillation are two emerging membrane technologies for the production of vapour as permeate, which, in addition to well-established pervaporation technology, are of increasing interest to academia and industry. As efficient separation and concentration processes, they have high potential for use in the energy, water, chemical, food and pharmaceutical sectors. Part One begins by covering the fundamentals, preparation and characterization of pervaporation, before going on to outline the associated systems and applications. State of the art uses, future trends and next generation pervaporation are then discussed. Part Two then explores the preparation, characterization, systems and applications of membranes for vapour permeation, followed by modelling and the new generation of vapour permeation membranes. Finally, Part Three outlines the fundamentals of membrane distillation and its applications in integrated systems, before the book concludes with a view of the next generation.

Related titles List of contributors Woodhead Publishing Series in Energy Preface Part One. Pervaporation 1. Fundamentals of pervaporation 1.1. Introduction 1.2. Fundamentals of mass and heat transfer in pervaporation 1.3. Process and technological matters in pervaporation 1.4. Concluding remarks and future trends 2. Pervaporation membranes: preparation, characterization, and application 2.1. Introduction 2.2. Pervaporation (PV) membrane materials 2.3. Characterization of pervaporation membranes 2.4. Membrane module configurations for pervaporation 2.5. Membranes for pervaporation applications 2.6. Future trends and conclusions 3. Integrated systems involving pervaporation and applications 3.1. Introduction to integrated systems involving pervaporation 3.2. Applications of integrated systems involving pervaporation 3.3. Conclusions and future trends 3.4. Sources of further information and advice 4. Pervaporation modeling: state of the art and future trends 4.1. Introduction 4.2. Fundamentals of pervaporation modeling 4.3. Applications to improve the efficiency of pervaporation 4.4. Conclusions 4.5. Future trends 4.6. Sources of further information and advice 5. Next-generation pervaporation membranes: recent trends, challenges and perspectives 5.1. Introduction 5.2. Modified ceramic membranes 5.3. Mixed matrix membranes 5.4. Bio-inspired membranes and membrane synthesis approaches 5.5. Supported liquid (SL) membranes 5.6. Final remarks and future trends 5.7. Sources of further information Part Two. Vapour permeation 6. Membranes for vapour permeation: preparation and characterization 6.1. Introduction 6.2. Polymer membranes 6.3. Zeolite membranes 6.4. Mixed matrix membranes 6.5. Future directions 7. Integrated systems involving membrane vapor permeation and applications 7.1. Introduction 7.2. Integrated systems involving membrane vapor separation 7.3. Applications of membrane vapor separation 7.4. Conclusion and sources of further information and advice 7.5. Future trends in development of membrane vapor separation 8. Vapour permeation modelling 8.1. Introduction 8.2. Fundamentals of vapour permeation modelling into dense polymeric membranes 8.3. Diffusion modelling 8.4. Solubility modelling 8.5. Vapour permeation in mixed matrix membranes and heterogeneous systems 8.6. Future trends 8.7. Conclusions 9. New generation vapour permeation membranes 9.1. Introduction 9.2. Current limitations of vapour permeation (VP) 9.3. Emerging VP membrane materials 9.4. Emerging membrane module configurations 9.5. Emerging applications for VP 9.6. Conclusions and future trends 9.7. Sources of further information Part Three. Membrane distillation 10. Fundamentals of membrane distillation 10.1. Introduction: nonisothermal membrane processes 10.2. Key characteristics of membrane distillation 10.3. Types of membranes and membrane module configurations for membrane distillation 10.4. Membrane distillation theory 10.5. Typical application of membrane distillation technology 10.6. Conclusions 10.7. Future trends and sources of further information and advice 11. Membranes used in membrane distillation: preparation and characterization 11.1. Introduction 11.2. Materials for membrane distillation (MD) membranes 11.3. Design and fabrication of MD membranes 11.4. Characterization of MD membranes 11.5. MD membrane modules and testing of MD membranes 11.6. Conclusions and future trends 11.7. Sources of further information and advice 12. Integrated systems involving membrane distillation and applications 12.1. Introduction 12.2. Applications of membrane distillation in desalination 12.3. Other applications of membrane distillation 12.4. Integrated systems involving membrane distillation 12.5. Conclusions and future trends 12.6. Sources of further information 13. Modelling of pore wetting in membrane distillation compared with pervaporation 13.1. Introduction 13.2. Fundamentals of membrane distillation (MD) modelling and improvement 13.3. Review of experimental works on MD membrane pore wetting 13.4. Development of a theoretical model for pore wetting in vacuum MD 13.5. Conclusions and future directions 14. Next generation membranes for membrane distillation and future prospects 14.1. Introduction 14.2. Materials for membrane distillation 14.3. Emerging module configurations for membrane distillation 14.4. Conclusions and future trends Index