Current Trends and Future Developments on (Bio-) Membranes Techniques of Computational Fluid Dynamic (CFD) for Development of Membrane Technology
Current Trends and Future Developments on (Bio-) Membranes: Techniques of Computational Fluid Dynamic (CFD) for Development of Membrane Technology provides updates on new progress in membrane processes due to various challenges and how many industrial companies and academic centers are carrying out these processes. Chapters help readers understand techniques of computational fluid dynamic (CFD) for the development of membrane technology, including an introduction to the technologies, their applications, and the advantages/disadvantages of CFD modeling of various membrane processes. In addition, the book compares these modeling methods with other traditional separation systems and covers fouling and concentration polarization problems.
The book is a key reference for R&D managers interested in the development of membrane technologies as well as academic researchers and postgraduate students working in the wider areas of strategic treatments, separation and purification processes.
2. Application of CFD technique in UF/MF processes
3. Application of CFD technique in RO/NF processes
4. Application of CFD technique in ED/RED processes
5. Application of CFD technique in MD processes
6. Application of CFD technique in dialysis processes
7. Application of CFD technique in Pervaporation processes
8. Application of CFD technique in processes of gas membrane separation
9. Application of CFD technique in membrane contactor systems
10. Application of CFD technique in membrane reactor (MR) systems
11. Application of CFD technique in membrane bioreactor (MBR) systems
Angelo Basile, a Chemical Engineer with Ph.D. in Technical Physics, is author of hundreds of papers, books, chapter-books, and Special Issues in the field of Membrane Science and Technology, with also various Italian, European and worldwide patents. He is an Associate Editor of various int. journals (IJHE, APCEJ, etc), Editor-in-Chief of the Int. J. Membrane Sci. & Techn., and member of the Editorial Board of more 25 int. journals. Today Basile is working at General TAG, Via Mastri Ligornettesi n. 28, Ligornetto 6853 – Switzerland.
Kamran Ghasemzadeh is an associate professor in the Faculty of Chemical Engineering at the Urmia University of Technology, Iran where he has been a faculty member since 2014. From 2016-2018, also, he was nominated as head of chemical engineering faculty. On the other hand, from August 2018, he is nominated as director of UUT research center in Urmia university of technology. His research interests lie in the area of membrane and membrane reactor processes, ranging from modeling to design to implementation. In recent years, he has focused on study of inorganic membranes (graphene, silica and palladium membranes) performances for gas separation and water treatment from both aspects of experimental and modeling point of views. He has collaborated actively with researchers in several other disciplines of chemical engineering, particularly simulation of chemical processes by commercial Comsol Multiphysics, Fluent and Aspen Hysys software. Moreover, he has succeeded to publish more than seventy ISI and conference papers, two patents, seven books and also more than forty book chapters. Hence, Kamran has served on roughly twenty conference and workshop program committees.
- Includes developments of membrane technologies in different applications by using CFD tools
- Describes CFD methods for evaluation and optimization of membrane process performance
- Indicates CFD method advantages over other modeling strategies for the analysis of membrane/membrane reactor processes
Date de parution : 12-2021
Ouvrage de 402 p.
19x23.4 cm
Mots-clés :
?Absorption; CFD; CFD method; CFD simulations; Computational fluid dynamics; Dialysis-based processes; Dimensionless correlations; Direct numerical simulations; Donnan dialysis; Electrodialysis; Finite difference; Finite element; Finite volume; Flow hydrodynamics; Fouling simulation; Gas separation; Hemodialysis; Hollow fiber; Mathematical modeling; Membrane; Membrane bioreactor; Membrane contactor; Membrane development; Membrane filtration; Membrane packing density; Membrane reactor; Microfiltration; Modeling; Modeling study; Multiphase flow; Nanofiltration; Nanofluid; Neutralization dialysis; Numerical modeling; Numerical simulation; Overlimiting transport; Pervaporation; Piezodialysis; Reverse electrodialysis; Reverse osmosis; Separation and purification; Separation processes; Simulation; Simulation methods; Sludge rheology; Spiral-wound module; Turbulence model; Ultrafiltration
