Handbook of Thermal Management Systems: e-Mobility and Other Energy Applications is a comprehensive reference on the thermal management of key renewable energy sources and other electronic components. With an emphasis on practical applications, the book addresses thermal management systems of batteries, fuel cells, solar panels, electric motors, as well as a range of other electronic devices that are crucial for the development of sustainable transport systems. Chapters provide a basic understanding of the thermodynamics behind the development of a thermal management system, update on Batteries, Fuel Cells, Solar Panels, and Other Electronics, provide a detailed description of components, and discuss fundamentals.
Dedicated chapters then systematically examine the heating, cooling, and phase changes of each system, supported by numerical analyses, simulations and experimental data. These chapters include discussion of the latest technologies and methods and practical guidance on their application in real-world system-level projects, as well as case studies from engineering systems that are currently in operation. Finally, next-generation technologies and methods are discussed and considered.
- Presents a comprehensive overview of thermal management systems for modern electronic technologies related to energy production, storage and sustainable transportation
- Addresses the main bottlenecks in the technology development for future green and sustainable transportation systems
- Focuses on the practical aspects and implementation of thermal management systems through industrial case studies, real-world examples, and solutions to key problems
1. Basics of Heat Transfer: Conduction
2. Basics of Heat Transfer: Convection
3. Basics of Heat Transfer: Heat Exchanger
4. Introduction to battery systems
5. Redox Flow Batteries membranes: overview and advances
6. Need of Battery Thermal Management System
7. Battery thermal modelling: models and prospects
8. Battery Thermal Modelling and Effective Cooling.heating Methods
9. Evaluation of heat generation and application in liquid cooling of Li-ion
battery packs
10. Battery Thermal Management Through Simulation and Experiment: Air Cooling
and Enhancement
11. Battery thermal management through simulation and experiment (liquid
cooling.heating)
12. Simulations of 3D Inhomogeneous Temperature Distributions in Li-Ion Pouch
Cells with Passive Thermal Management
13. A Novel Cooling Strategy for Lithium-Ion Battery Thermal Management with
Phase Change Material
14. Passive Thermal Management Systems for e-mobility using PCM composites
15. Comparison of Air, Liquid and Phase Change Material for Battery Thermal
Management
16. Fuel Cells Basics and Types
17. Fuel Cell Technology Overview and Aspects of System Integration
Science
18. Recent advancements and prospects of thermal management strategies in
polymer electrolyte membrane Fuel cells (PEMFC)
19. Thermal stress modelling of solid oxide fuel cell stacks based on
multi-physics numerical method
20. Thermal modelling and performance assessment of a PEM fuel cell
21. Air cooled fuel cells: simulation and experiments
22. Water cooled fuel cell: simulation and experiments
23. Liquid-cooling PEM fuel cell thermal management: Fundamental
configuration, numerical simulation, control algorithm and experimental
verification
24. Futuristic methods of fuel cell cooling
25. Introduction to Solar Panels
26. Cooling technologies for efficiency enhancement of solar PV panels: A
review
27. Enhancing the Efficiency of Solar Photovoltaic Systems by Using Liquid
cooling Techniques
28.Liquid-based solar panel cooling and PV.T systems
29. Improvement of solar panel performance using phase change material
30. Thermal management of PV Panels for Enhanced performance using PCM
31. Solar panel cooling using hybrid cooling systems
32. Hybrid cooling systems for enhancing the electrical performance of solar
photovoltaic (PV) panels
33. The effect of thermal treatments on photovoltaic module Recycling
34. Review of Phase change materials
35. Strategies for Thermal management of electronics: Design, Development,
and Application
36. Futuristic methods of electronics cooling
37. Experimental and Numerical Study of PCM Based Heat Sink for Thermal
Management Electronic Chips
38. Mechanism of flow boiling in microchannels and structure optimization of
heat changers used in pumped two-phase cooling system for data center
cooling
39. Waste-heat driven Stirling engine systems: Conception and Parameters
40. Thermal and catalytic pyrolysis of date palm stones: Production,
characterization of pyrolytic oil and study of performance and emission
characteristics in CI engine
41. Experimental Investigation of Performance and Exhaust Emissions of
Pyrolytic Olive Pomaces biofuels blends without and with additives fuelled
Internal Combustion Engine
42. Experimental and multi-scale numerical study of air-flue gas heat
exchanger in a biomass boiler
INSA Hauts-de-France, LAMIH UMR CNRS 8201, Université Polytechnique Hauts-de-France, Campus Mont-Houy, F-59313 Valenciennes Cedex 9, France.
Prof. Fethi ALOUI has published around 100 journal papers, more than 135 conference papers (53 with DOI), 6 published books (ISBN and DOI), 2 published conference proceedings (ISBN) and 26 book chapters (with DOI). He was the organizer of 3 international conferences and the co-organizer of many other international conferences and symposia, among them (and in each year since 2010 until 2017) the ASME-FEDSM Symposium on Transport Phenomena in Energy Conversion from Clean and Sustainable Resources. He is the Associate Editor of the Journal of Applied Fluid Mechanics since 2008 and was the Associate Editor of International Journal of Energy Research from 2013 until 2022.
Prof. Edwin Geo Varuvel has published papers in 70 international journals, 16 international conferences and 16 national conferences. He has eight years of research and 18 years of teaching experience in engineering level. He worked for Ecole des Mines de Nantes, France for about two years as a research engineer in the field of waste biofuels. He is a reviewer for more than 20 international journals. He has handled more than ten research projects in the field of alternate fuels for automobiles. He was awarded with 18,000 by AICTE India to develop an electronically controlled high performance RSO-hydrogen dual fuel engine. Currently, he is working on two sponsored research projects on system identification of Biodiesel-hydrogen dual fuel engine and liquid fuel production from waste oils under selective excellence. Dr. Ankit Sonthalia is currently working as an Assistant Professor in the Department of Automobile Engineering, SRM Institute of Science and Technology. He has published more than 20 papers in international journals. He is reviewer of six international journals. He is a member of Society of Automobile Engineer. His research interests include waste to energy, thermal management, emission control and hydrogen.
