Materials for Advanced Heat Transfer Systems
- 1st Edition - November 26, 2022
- Editors: S. J. Vijay, Brusly Solomon, Josua Meyer
- Language: English
- Paperback ISBN:9 7 8 - 0 - 3 2 3 - 9 0 4 9 8 - 8
- eBook ISBN:9 7 8 - 0 - 3 2 3 - 9 0 4 9 9 - 5
Materials for Advanced Heat Transfer Systems presents the latest research and technologies developed for high-performance materials in heat transfer and cooling. The book compiles… Read more
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Request a sales quoteMaterials for Advanced Heat Transfer Systems presents the latest research and technologies developed for high-performance materials in heat transfer and cooling. The book compiles sought after research academics and industry experts need to adopt to solve common problems in critical areas of heat transfer and cooling to help advance the field further. A variety of methodologies are included to synthesize the material used, along with the correct procedures to follow to ensure appropriate and effective use. Various case studies are presented to help the reader further understand the benefits and challenges of the materials discussed.
Researchers, academics, students and engineers working on heat transfer systems will benefit from this interdisciplinary and applications-focused reference and be guided through various methodologies to make informed decisions based on the latest research and technologies available.
- Presents current and futuristic materials that are being synthesized or used for improving heat transfer mechanisms of a system
- Applies the technologies, models and methods to a variety of applications, including power generation, aerospace, electronics and automobiles
- Includes recent case studies which exemplify the concepts and technologies analyzed
Researchers, academics, graduate students and engineers working on heat transfer systems. Policy makers; electronic cooling industries
- Cover image
- Title page
- Table of Contents
- Copyright
- Contributors
- Preface
- Chapter 1. Nanofluids for heat transfer augmentation
- 1.1. Introduction
- 1.2. Preparation of nanofluid
- 1.3. Stability of nanofluid
- 1.4. Stability enhancement methods of nanofluid
- 1.5. Thermophysical properties of nanofluid
- 1.6. Heat transfer characteristics of nanofluids
- 1.7. Conclusion
- 1.8. Abbreviations
- Chapter 2. Natural convection heat transfer enhancement using nanofluids
- 2.1. Introduction
- 2.2. Recent studies of nanofluid's efficacy in natural convection heat transfer
- 2.3. Mathematical modeling
- 2.4. Conclusion
- Chapter 3. From 2007 to 2021: present state of research on hybrid nanofluids as advanced thermal fluids
- 3.1. Introduction
- 3.2. Methodology
- 3.3. Hybrid nanofluid research growth and associated disciplines
- 3.4. Studied nanoparticles and base fluids
- 3.5. Thermal, tribological, and optical properties
- 3.6. Convective heat transfer using hybrid nanofluids
- 3.7. Application of HNFs for enhanced performance
- 3.8. HNFR performance
- 3.9. Funding
- 3.10. Future research outlook and concluding remarks
- Chapter 4. Heat transfer applications of hybrid nanofluids in machining and thermal systems
- 4.1. Introduction
- 4.2. Hybrid nanofluids
- 4.3. Applications of hybrid nanofluids
- 4.4. Summary
- Chapter 5. Al₂O₃/HFE based thermosyphon for heat transfer enhancement
- 5.1. Introduction
- 5.2. Experimental procedure
- 5.3. Data reduction
- 5.4. Results and discussion
- 5.5. Conclusions
- Chapter 6. Oxide coatings for phase change heat transfer enhancement
- 6.1. Introduction
- 6.2. Effect of metallic nanoparticle coating on the heat transfer enhancement
- 6.3. Effects of oxide coating on the heat transfer enhancement of heat pipes
- 6.4. Effect of anodization on the heat transfer performance of heat pipes and thermosyphons
- 6.5. Influence of coating on pool boiling heat transfer and convective heat transfer
- 6.6. Inferences from the thermal resistance and heat transfer coefficient comparison of heat pipes–coated surfaces
- 6.7. Summary of heat transfer mechanisms involved in coated heat pipes
- 6.8. Conclusion
- Chapter 7. Heat transfer enhancement in phase change material for electronic cooling applications
- 7.1. Introduction
- 7.2. Cooling methods for electronic equipment
- 7.3. Phase change material
- 7.4. Preparation of nano enhanced phase change material (NE-PCM)
- 7.5. Measurement of thermal conductivity of nano-enhanced PCM
- 7.6. Energy stored in the phase change material
- 7.7. Conclusions
- Chapter 8. Advanced wick materials and structures for loop heat pipes
- 8.1. LHP components and operation
- 8.2. Introduction to wicks
- 8.3. Previous research on different wicks used in LHPs
- 8.4. Application of copper mesh wick in LHP
- 8.5. Conclusions
- Chapter 9. A comprehensive characterization of shape memory alloys concerning the attributes of fabrication and post machining responses
- 9.1. Introduction
- 9.2. Additive manufacturing processes used for SMAs
- 9.3. Shape memory alloys used for biomedical applications
- 9.4. Cooling system–based shape memory alloy machining
- 9.5. Nonconventional machining operations for shape memory alloy materials
- 9.6. Surface integrity analysis of shape memory alloy
- 9.7. Conclusion
- Index
- No. of pages: 356
- Language: English
- Edition: 1
- Published: November 26, 2022
- Imprint: Woodhead Publishing
- Paperback ISBN: 9780323904988
- eBook ISBN: 9780323904995
SV
S. J. Vijay
Dr. Santhiyagu Joseph Vijay is an Associate Professor in the Department of Mechanical Engineering of Karunya Institute of Technology and Sciences. He completed his graduate study in the field of CAD/CAM. He is a Doctorate in the field of Materials and Manufacturing. He was also a Post-doctoral fellow in Jeonju University, South Korea during 2016-17. He has carried out research in developing metal matrix composites through various manufacturing techniques. He is also into synthesizing of nano-materials for electromagnetic shielding applications. To his credit he has published over 50 journal paper in peer-reviewed journals in the fields of friction stir welding, composites, nano-materials and additive manufacturing. He has also published 4 patents on composites and additive manufacturing. He is currently carrying out 4 major funded projects worth USD 250,000 and developing multi-material structural panel for defense sector and a novel manufacturing technology for aeronautical sector.
Affiliations and expertise
Associate Professor, Karunya Institute of Technology and Sciences, Coimbatore, IndiaBS
Brusly Solomon
Dr. Brusly Solomon is an Associate Professor in the Department of Mechanical Engineering at Karunya Institute of Technology and Sciences (KITS), Coimbatore. He joined as Research Associate in the Dean Research office of the KITS in the year 2006. His research focuses on the development of phase change cooling devices such as heat pipes and thermosyphons and vapor chambers with nanofluids and various wick materials. He pursued his Post-doctoral research in the Thermo fluids Research Laboratory of Department of Mechanical and Aeronautical Engineering, University of Pretoria. He is recipient of Govt. of India, Young Scientist Award 2015 by Science and Engineering Research board, Young Achievers Award 2015 by Karunya Institute of Technology and Sciences, UP postdoctoral fellowship 2015 by University of Pretoria. His research interests include Phase change heat transfer, electronic cooling with heat pipes, natural convection heat transfer and Magnetic nanofluids. Currently, he is reviewer of many technical journals from Elsevier, Wiley, Springer, Tailor and Francis and many other Publications.
Affiliations and expertise
Associate Professor, Karunya Institute of Technology and Sciences, Coimbatore, IndiaJM
Josua Meyer
Professor Josua Meyer is a member or fellow of various professional institutes and societies such as ASME, ASHRAE, AIAA, and the Royal Aeronautical Society. He is registered as a professional engineer by the Engineering Council of South Africa. He is leading the Clean Energy Research unit that he established with a broad focus on thermal sciences and fluid flow, but with a narrower focus on heat exchangers. His heat exchanger work focused on fundamental work of flow in the transitional flow regime, mixed convection, nanofluids, boiling, and condensation. On an applications level his work focuses on thermal-solar-, wind- and nuclear energy. He has received 11 different national teaching awards from three different universities, as well as an international award, in 2013, for “Best professor in mechanical and aeronautical engineering”. He has won more than 45 research awards including 25 awards for best article of the year or best conference paper. His is a “highly cited researcher” according to the ISI, and ranked among the top 0.1% in engineering. He is on the editorial board of 13 journals and is editor of 7 journals in his field of research.
Affiliations and expertise
Professor, University of Pretoria, South AfricaRead Materials for Advanced Heat Transfer Systems on ScienceDirect