Fundamental modeling of membrane systems : membrane and process performance /

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Fundamental Modelling of Membrane Systems: Membrane and Process Performance summarizes the state-of-the-art modeling approaches for all significant membrane processes, from molecular transport, to process level, helping researchers and students who carry out experimental research save time and accur...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Luis, Patricia (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Amsterdam, Netherlands : Elsevier, [2018]
Temas:
Membranes (Technology)
Membranes (Technologie)
SCIENCE > Chemistry > Industrial & Technical.
TECHNOLOGY & ENGINEERING > Chemical & Biochemical.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Intro; Title page; Table of Contents; Copyright; Dedication; Contributors; Chapter 1: Introduction; Abstract; 1.1 General Overview of Technologies; 1.2 Kind of Membranes and the Implications in Modeling; 1.3 Mass Transfer in Laminar and Turbulent Flow; 1.4 Mass Transfer Through Membranes; 1.5 Polarization and Fouling Phenomena; Chapter 2: Microfiltration, ultrafiltration, nanofiltration, reverse osmosis, and forward osmosis; Abstract; 2.1 Introduction; 2.2 Process Description and Operating mode; 2.3 General Overview of Applications; 2.4 System Configuration; 2.5 Hydraulic Resistance
  • 2.6 Modeling of Microfiltration (MF)2.7 Modeling of Ultrafiltration (UF); 2.8 Modeling of Nanofiltration (NF); 2.9 Modeling of Organic Solvent Nanofiltration (OSN); 2.10 Modeling of Reverse Osmosis (RO); 2.11 Modeling of Forward Osmosis (FO); 2.12 Module Performance; 2.13 Conclusions; Chapter 3: Pervaporation; Abstract; 3.1 Process Description; 3.2 General Overview of Applications; 3.3 Mass Transfer in Pervaporation; 3.4 Interpretation of Pervaporation Results; 3.5 McCabe-Thiele Diagram; 3.6 Coupling Effects; 3.7 Concluding Remarks; Chapter 4: Gas permeation and supported liquid membranes
  • Abstract4.1 Process Description; 4.2 General Overview of Applications; 4.3 Mass Transfer in Gas Permeation; 4.4 Mass Transfer in SLMs; 4.5 Interpretation of Results; 4.6 Concluding Remarks; Chapter 5: Membrane contactors; Abstract; 5.1 Process Description; 5.2 Mathematical Description of Mass Transfer in a Membrane Contactor; 5.3 Membrane-based Absorption; 5.4 Membrane-based Solvent Extraction; 5.5 Membrane distillation-crystallization; 5.6 Membrane Emulsification; 5.7 Contactor Membrane Reactors; Chapter 6: Membrane bioreactors; Abstract; 6.1 Process Description
  • 6.2 General Overview of Applications6.3 Design of Membrane Bioreactors; 6.4 Monitoring and Control of Membrane Bioreactors; 6.5 Modeling of Membrane Bioreactors; 6.6 Conclusions and Outlook; Chapter 7: Ion-exchange membrane systems-Electrodialysis and other electromembrane processes; Abstract; 7.1 Introduction; 7.2 Process Description; 7.3 General Overview of Applications; 7.4 Calculation of Selectivity in Electrodialysis; 7.5 Ion Transport Through Ion-Exchange Membranes; 7.6 Other Configurations of Electrodriven Membrane Processes; 7.7 Conclusions
  • Chapter 8: Hybrid processes based on membrane technologyAbstract; 8.1 Introduction; 8.2 Hybrids Based on Pressure-Driven Processes; 8.3 Hybrid Processes Based on Pervaporation; 8.4 Hybrid Processes Based on Gas Permeation; 8.5 Hybrid Processes Based on Membrane Contactors; 8.6 Hybrid Processes Based on Membrane Bioreactors; 8.7 Hybrids Based on Electro-Driven Processes; Index

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