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Elsevier

Shell-and-Tube Latent Heat Storage Systems

Advanced Techniques for Heat Transfer Enhancement and Performance Improvement

  • 1st Edition - January 1, 2027
  • Latest edition
  • Authors: Pouyan Talebizadehsardari, Khashayar Hosseinzadeh, Mehdi Mahboobtosi
  • Language: English

Shell-and-Tube Latent Heat Storage Systems: Advanced Techniques for Heat Transfer Enhancement and Performance Improvement addresses the critical challenges in thermal energy storag… Read more

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Description

Shell-and-Tube Latent Heat Storage Systems: Advanced Techniques for Heat Transfer Enhancement and Performance Improvement addresses the critical challenges in thermal energy storage, focusing on latent heat storage technologies using phase change materials. The book provides a structured exploration of advanced design enhancements, including innovative fin geometries, nanoparticles, porous media, and geometry modifications for both double-pipe and triple-pipe, horizontal and vertical configurations. Each chapter offers foundational principles, analytical methods, real-world case studies, and simulation data, enabling readers to understand and apply the latest research in system optimization.

The modular chapter format ensures that content is accessible independently, supporting both academic research and professional practice. As the demand for renewable energy and efficient thermal management rises, this reference meets the need for integrated, practical solutions to optimize system performance, bridging the gap between theory and industrial applications. The reference empowers researchers, engineers, and students to develop scalable, cost-effective thermal energy storage solutions. By integrating the latest advances in materials science and system design, the reference supports the energy transition, reduces CO2 emissions, and aligns with global sustainability goals.

Key features

  • Presents advanced design strategies for latent heat storage systems, including the utilization of fins, nanoparticles, and porous media
  • Offers practical strategies for optimizing and implementing latent heat storage systems, addressing real-world challenges such as slow charging and discharging rates, inefficient heat transfer, and suboptimal system performance across diverse operating conditions
  • Utilizes case studies, numerical simulations, and performance analyses to demonstrate how various design improvements affect system performance under different conditions, providing practical insights for professionals, researchers, and students
  • Examines the cost-effectiveness, scalability, and implementation challenges of advanced thermal energy systems, connecting academic research with practical industrial applications
  • Includes a concise section on the economic feasibility and lifecycle assessment of advanced latent heat storage systems to enhance its relevance for industry professionals

Readership

Researchers and engineers in thermal energy storage systems

Table of contents

1. Introduction

2. Horizontal Double-Pipe Heat Storage System Enhanced by Fins Addition

3. Horizontal Double-Pipe Heat Storage System Enhanced by Nanoparticles, Fins, Geometry Modification, and Porous Media

4. Vertical Double-Pipe Heat Storage Systems Enhanced by Fins Addition

5. Vertical Double-Pipe Heat Storage Systems Enhanced by Geometry Modification, Porous Medium, and Nanoparticles

6. Horizontal Triple-Pipe Heat Storage System Enhanced by Fins Addition

7. Horizontal Triple-Pipe Heat Storage System Enhanced by Geometry Modifications and Nanoparticles

8. Vertical Triple-Pipe Heat Storage System Enhanced by Fins Addition

9. Vertical Triple-Pipe Heat Storage System: Effect of Geometry Modification, Porous Medium, and Nanoparticles

10. Shell-and-multi tube heat storage systems: Effect of geometry modifications, fins addition and porous media implementation

Product details

  • Edition: 1
  • Latest edition
  • Published: January 1, 2027
  • Language: English

About the authors

PT

Pouyan Talebizadehsardari

Pouyan Talebizadehsardari is currently a Senior Research Fellow in the Faculty of Engineering at the University of Nottingham. He earned his B.Sc. (2008), M.Sc. (2011), and Ph.D. (2016) in Mechanical Engineering. His research focuses on a wide range of topics, including thermal energy storage, thermal management of batteries and electric motors, computational fluid dynamics (CFD), phase change materials, two-phase flow, particle deposition and dispersion, turbulent flows, heat and mass transfer, and pollution control.

To date, Dr. Talebizadehsardari has published over 180 ISI-indexed journal articles and has contributed to more than 15 industrial projects. He has been recognized among the top 2% of scientists worldwide in the 2020–2021 and 2023–2024 global rankings. He also serves as an Associate Editor for the journal Heat Transfer Engineering (Taylor & Francis).

Affiliations and expertise
Senior Research Fellow, Faculty of Engineering, University of Nottingham, UK

KH

Khashayar Hosseinzadeh

Khashayar Hosseinzadeh is Assistant Professor of mechanical engineering, University of Mazandaran, Babolsar‎ and researcher in the field of Mechanical Engineering-Energy Conversion, holding a Post-Doctoral Fellowship at Sharif University of Technology. He earned his Ph.D. in Mechanical Engineering-Energy Conversion from Babol Noshirvani University of Technology, Iran. Dr. Hosseinzadeh's expertise spans a wide range of topics within the realm of mechanical engineering and energy conversion. His primary research interests include Energy Storage Systems, Phase Change Materials, Photovoltaic Thermal Hybrid Solar Collectors, Energy Management, Mini Channel Heat Sinks, Micro Mixers, Heat Exchangers, Multi-phase Flow, Thermosyphon, Nanofluids, Non-Newtonian Fluids, Porous Media, HVAC (Heating, Ventilation, and Air Conditioning), Analytical Methods, and Computational Fluid Dynamics (CFD). Dr. Hosseinzadeh has received significant recognition for his contributions to the field, being acknowledged as one of the World's Top 1% Scientists by both the Web of Science (WOS) and Essential Science Indicators (ESI) in 2022 and 2023. Additionally, he has been consistently recognized in the top 2% of scientists worldwide by Stanford University in the years 2020, 2021, 2022, and 2023. He is the author of the book FlexPDE and Finite Element Method Applications in Thermal Energy Storage and Cavities.

Affiliations and expertise
Assistant Professor of Mechanical Engineering, University of Mazandaran, Babolsar‎, Iran

MM

Mehdi Mahboobtosi

Mehdi Mahboobtosi is a Ph.D. in Mechanical Engineering, Energy Conversion, at Noshirvani University of Technology, Babol. He was among the top students in his studies. He is the author of more than 21 scientific articles and one book. He is the author of the book FlexPDE and Finite Element Method Applications in Thermal Energy Storage and Cavities. He is a researcher in energy conversion mechanical engineering. His research interests include phase change materials, energy storage systems, Machine Learning, Python, nanofluids, hydrogen liquefaction, energy management, heat exchangers, nonlinear methods in solving engineering problems.
Affiliations and expertise
Ph.D. in Mechanical Engineering, Energy Conversion, Noshirvani University of Technology, Babol, Iran