Design And Development Of Efficient Energy Systems

There is not a single industry which will not be transformed by machine learning and Internet of Things (IoT). IoT and machine learning have altogether changed the technological scenario by letting the user monitor and control things based on the prediction made by machine learning algorithms. There has been substantial progress in the usage of platforms, technologies and applications that are based on these technologies. These breakthrough technologies affect not just the software perspective of the industry, but they cut across areas like smart cities, smart healthcare, smart retail, smart monitoring, control, and others. Because of these “game changers,” governments, along with top companies around the world, are investing heavily in its research and development. Keeping pace with the latest trends, endless research, and new developments is paramount to innovate systems that are not only user-friendly but also speak to the growing needs and demands of society. This volume is focused on saving energy at different levels of design and automation including the concept of machine learning automation and prediction modeling. It also deals with the design and analysis for IoT-enabled systems including energy saving aspects at different level of operation. The editors and contributors also cover the fundamental concepts of IoT and machine learning, including the latest research, technological developments, and practical applications. Valuable as a learning tool for beginners in this area as well as a daily reference for engineers and scientists working in the area of IoT and machine technology, this is a must-have for any library.

There is not a single industry which will not be transformed by machine learning and Internet of Things (IoT). IoT and machine learning have altogether changed the technological scenario by letting the user monitor and control things based on the prediction made by machine learning algorithms. There has been substantial progress in the usage of platforms, technologies and applications that are based on these technologies. These breakthrough technologies affect not just the software perspective of the industry, but they cut across areas like smart cities, smart healthcare, smart retail, smart monitoring, control, and others. Because of these “game changers,” governments, along with top companies around the world, are investing heavily in its research and development. Keeping pace with the latest trends, endless research, and new developments is paramount to innovate systems that are not only user-friendly but also speak to the growing needs and demands of society. This volume is focused on saving energy at different levels of design and automation including the concept of machine learning automation and prediction modeling. It also deals with the design and analysis for IoT-enabled systems including energy saving aspects at different level of operation. The editors and contributors also cover the fundamental concepts of IoT and machine learning, including the latest research, technological developments, and practical applications. Valuable as a learning tool for beginners in this area as well as a daily reference for engineers and scientists working in the area of IoT and machine technology, this is a must-have for any library.

System-Level Design Techniques for Energy-Efficient Embedded Systems addresses the development and validation of co-synthesis techniques that allow an effective design of embedded systems with low energy dissipation. The book provides an overview of a system-level co-design flow, illustrating through examples how system performance is influenced at various steps of the flow including allocation, mapping, and scheduling. The book places special emphasis upon system-level co-synthesis techniques for architectures that contain voltage scalable processors, which can dynamically trade off between computational performance and power consumption. Throughout the book, the introduced co-synthesis techniques, which target both single-mode systems and emerging multi-mode applications, are applied to numerous benchmarks and real-life examples including a realistic smart phone.

The management of global warming is a relevant issue throughout the world and has experts of various fields considering various methods to control Earth’s atmospheric temperature. While microgrid technology is emerging as the next generation energy supply system, renewable energy is often unstable and requires the support of conventional energy equipment. Optimum Design of Renewable Energy Systems: Microgrid and Nature Grid Methods investigates the development of highly efficient energy storage equipment and of operation optimization technology of compound energy systems. This book is an essential reference source for technical consultants, urban environment engineers, and energy researchers interested in the development of efficient energy systems and operation optimization technology.

RENEWABLE AND EFFICIENT ELECTRIC POWER SYSTEMS Join the energy revolution—this comprehensive resource offers quantitative and practical approaches for designing a sustainable, 21st-century electricity system, covering renewable generation technologies, conventional power plants, energy efficiency, storage, and microgrids. Renewable and Efficient Electric Power Systems dives into the fundamentals of modern electricity systems, introducing key technologies, economic and environmental impacts, and practical considerations for energy and climate professionals. The book explains the science and engineering underlying renewable energy—including solar, wind, and hydropower—along with an expanded set of key energy technologies such as fuel cells, batteries, and hydrogen. This updated edition prepares readers to participate in the world’s ongoing efforts to decarbonize the electricity sector and move toward a more sustainable future. The book covers foundational knowledge of electric power, up through current developments and future prospects for renewable energy. The update significantly expands core content to address topics such as energy efficiency, smart grids, energy storage, and microgrids. It reframes energy as an integral factor in urban development and highlights forward-looking strategies to decarbonize the built environment. The text draws on a multi-scalar approach that ranges from utility-scale to building-scale to assess energy systems, and further considers centralized vs. distributed system architecture. The authors integrate perspectives from engineering professionals across different sectors, incorporating relevant insights from applied projects, with an eye toward implementing energy systems in the real world. Given the textbook’s broad reach, this edition situates energy development in an international context and provides examples relevant to a global audience. An essential resource for engineers and other practitioners working in climate and energy, offering cutting-edge frameworks and quantitative approaches to energy system design. Early chapters develop the skills and knowledge necessary for students and professionals entering the clean energy field. Later chapters offer an excellent bridge to prepare advanced students for further study in power engineering, or who intend to pursue policy or economic analysis. Step-by-step explanations of quantitative analysis are supplemented with additional practice problems to encourage self-instruction or complement classroom use. Accessible explanations provide planners and policymakers with fundamental technical understanding of energy systems. Combines pure technical analysis with economic and environmental considerations, and explores the link between energy, carbon, and new digital technologies, to provide a more comprehensive approach to energy education. As the world undergoes a transformation in energy and electricity, Renewable and Efficient Electric Power Systems is an indispensable text for students of energy, environment, and climate, as well as for practitioners seeking to refresh their understanding of renewable energy systems.

Design and Performance Optimization of Renewable Energy Systems provides an integrated discussion of issues relating to renewable energy performance design and optimization using advanced thermodynamic analysis with modern methods to configure major renewable energy plant configurations (solar, geothermal, wind, hydro, PV). Vectors of performance enhancement reviewed include thermodynamics, heat transfer, exergoeconomics and neural network techniques. Source technologies studied range across geothermal power plants, hydroelectric power, solar power towers, linear concentrating PV, parabolic trough solar collectors, grid-tied hybrid solar PV/Fuel cell for freshwater production, and wind energy systems. Finally, nanofluids in renewable energy systems are reviewed and discussed from the heat transfer enhancement perspective. Reviews the fundamentals of thermodynamics and heat transfer concepts to help engineers overcome design challenges for performance maximization Explores advanced design and operating principles for solar, geothermal and wind energy systems with diagrams and examples Combines detailed mathematical modeling with relevant computational analyses, focusing on novel techniques such as artificial neural network analyses Demonstrates how to maximize overall system performance by achieving synergies in equipment and component efficiency

Energy-Efficient Electrical Systems for Buildings, Second Edition offers a systematic and practical approaches to design and analyze electrical distribution and utilization systems in buildings. It considers safety and energy efficiency, while also focusing on sustainability and resiliency, to design electrical distribution systems for buildings. In addition, the second edition provides guidelines on how to design electrified and energy-resilient buildings. Utilizing energy efficiency, sustainability, and resiliency as important criteria, this book discusses how to meet the minimal safety requirements, set by the National Electrical Code (NEC), to select electrical power systems for buildings. It also considers the impact of building electrification on the design of electrical power systems. The second edition features a new chapter on the optimal design energy-efficient and resilient power systems. In addition, this book includes new end-of-chapter problems, examples, and case studies to enhance and reinforce student understanding. This book is intended for senior undergraduate mechanical, civil, and electrical engineering students taking courses in Electrical Systems for Buildings and Design of Building Electrical Systems. Instructors will be able to utilize an updated solutions manual and figure slides for their course.

This open access book addresses the issue of diffusing sustainable energy access in low- and middle-income contexts. Access to energy is one of the greatest challenges for many people living in low- income and developing contexts, as around 1.4 billion people lack access to electricity. Distributed Renewable Energy systems (DRE) are considered a promising approach to address this challenge and provide energy access to all. However, even if promising, the implementation of DRE systems is not always straightforward. The book analyses, discusses and classifies the promising Sustainable Product-Service System (S.PSS) business models to deliver Distributed Renewable Energy systems in an effective, efficient and sustainable way. Its message is supported with cases studies and examples, discussing the economic, environmental and socioethical benefits as well as its limitations and barriers to its implementation. An innovative design approach is proposed and a set of design tools are supplied, enabling readers to create and develop Sustainable Product-Service System (S.PSS) solutions to deliver Distributed Renewable Energy systems. Practical applications of the book’s design approach and tools by companies and practitioners are discussed and the book will be of interest to readers in design, industry, governmental institutions, NGOs as well as researchers.