Building Integrated Photovoltaic Thermal Systems: Fundamentals, Designs and Applications

Building Integrated Photovoltaic Thermal Systems: Fundamentals, Designs, and Applications is a comprehensive book that covers the fundamentals, designs, manufacturing, and installation techniques of building integrated photovoltaics. It addresses potential obstacles with current photovoltaic systems and introduces a hybrid system for building integrated thermal electric roofing. The book is useful for scientists and engineers in various fields.

Format: Paperback / softback
Length: 599 pages
Publication date: 02 November 2021
Publisher: Elsevier Science Publishing Co Inc

Building Integrated Photovoltaic Thermal Systems: Fundamentals, Designs, and Applications is a comprehensive guide that delves into the realm of integrating photovoltaic (PV) technology with thermal energy systems. This book offers a wealth of information on various applications, system designs, manufacturing processes, and installation techniques related to building integrated photovoltaics (BIPVT). It provides a thorough understanding of all system components, long-term performance, and testing, as well as the commercialization of BIPVT systems. By addressing potential obstacles encountered in traditional photovoltaic (PV) systems, such as efficiency bottlenecks and product heat harvesting, the authors not only delve into the fundamentals and design philosophy of BIPVT technology but also introduce a hybrid system for building integrated thermal electric roofing.

The topics covered in Building Integrated Photovoltaic Thermal Systems are of immense value to scientists and engineers specializing in photovoltaics, electrical and civil engineering, materials science, sustainable energy harvesting, solar energy, and renewable energy production. This book serves as a valuable resource for those seeking to advance their knowledge and expertise in this field.

The authors of Building Integrated Photovoltaic Thermal Systems have extensive experience in the research and development of BIPVT technology. They have conducted extensive studies on the performance of PV systems, thermal energy systems, and their integration. Their expertise in this area is evident in the detailed explanations and practical examples provided throughout the book.

The book is organized into five chapters, each covering a different aspect of BIPVT systems. Chapter 1 provides an introduction to the concept of BIPVT systems and their potential benefits. Chapter 2 explores the fundamentals of PV technology, including solar cell characteristics, module design, and system configurations. Chapter 3 delves into the design and optimization of BIPVT systems, considering factors such as solar irradiance, thermal load, and energy storage requirements. Chapter 4 discusses manufacturing processes and materials used in BIPVT systems, including solar cells, thermal collectors, and building components. Chapter 5 presents case studies and examples of successful BIPVT installations, showcasing the practical applications of this technology in various environments.

In addition to its theoretical aspects, Building Integrated Photovoltaic Thermal Systems provides practical insights into the challenges and opportunities associated with BIPVT systems. The authors discuss the potential for energy savings, greenhouse gas emissions reduction, and increased building efficiency through the integration of PV and thermal energy systems. They also address the regulatory framework, financing options, and market trends that are driving the growth of BIPVT technology.

One of the key strengths of this book is its comprehensive coverage of all system components. The authors provide detailed explanations of PV modules, thermal collectors, energy storage systems, and building envelope components, enabling readers to gain a deep understanding of the technical aspects of BIPVT systems. This information is invaluable for scientists and engineers who are involved in the design, development, and implementation of BIPVT systems.

Another notable feature of Building Integrated Photovoltaic Thermal Systems is its emphasis on long-term performance and testing. The authors discuss the methodologies used to evaluate the performance of BIPVT systems, including energy yield, thermal efficiency, and system durability. They also provide insights into the challenges associated with long-term performance monitoring and maintenance, ensuring that BIPVT systems remain reliable and efficient over their lifespan.

The commercialization of BIPVT systems is another important aspect covered in the book. The authors discuss the strategies and challenges involved in bringing BIPVT technology to market, including the need for collaboration between stakeholders, regulatory frameworks, and financing mechanisms. They also provide examples of successful BIPVT projects and case studies that demonstrate the economic viability and environmental benefits of this technology.

Building Integrated Photovoltaic Thermal Systems is a valuable resource for scientists, engineers, policymakers, and anyone interested in advancing the development and implementation of sustainable energy solutions. It provides a comprehensive understanding of BIPVT technology, covering its fundamentals, designs, and applications. The book's practical insights and case studies make it accessible to a wide range of readers, from students and researchers to professionals in the energy industry.

In conclusion, Building Integrated Photovoltaic Thermal Systems: Fundamentals, Designs, and Applications is a must-read for anyone seeking to advance their knowledge and expertise in the field of sustainable energy. With its comprehensive coverage of all system components, practical insights, and case studies, this book provides a valuable resource for scientists, engineers, policymakers, and anyone interested in advancing the development and implementation of sustainable energy solutions.

Weight: 1010g
Dimension: 153 x 233 x 31 (mm)
ISBN-13: 9780128210642