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The text comprehensively highlights the latest methodologies, models, techniques, and applications along with a description of modeling, optimization, and experimental works in the energy sector. It further explains key concepts such as finite element analysis tools, hybrid energy systems, mechanical components design, and optimization, solar coupled systems, and vertical heat exchanger. This book Discusses the role and integration of solar, geothermal, and hydrogen based thermal energy storage (TES) technologies in different sectors for space heating and cooling applications. Covers mechanical modeling and optimization of hybrid energy storage systems for performance improvement and focus on hydrogen production, storage and safety measures. Explores the integration of IoT and global energy interaction technologies, highlighting their potential benefits in driving the transition towards a sustainable and resilient global energy system. Explains different aspects of clean technologies like batteries, fuel cells, ground energy storage, solar thermal system and role of green hydrogen in decarbonizing sectors like transportation and energy. Showcases a clear idea of sustainable development using renewable energy, focusing on policymaking, challenges in transition from conventional to renewable energy and future directions in energy sector. It is primarily written for senior undergraduate, graduate students, and academic researchers in the fields of mechanical engineering, production engineering, industrial engineering, and environmental engineering.
The text comprehensively highlights the latest methodologies, models, techniques, and applications along with a description of modeling, optimization, and experimental works in the energy sector. It further explains key concepts such as finite element analysis tools, hybrid energy systems, mechanical components design, and optimization, solar coupled systems, and vertical heat exchanger. This book • Discusses the role and integration of solar, geothermal, and hydrogen‐based thermal energy storage (TES) technologies in different sectors for space heating and cooling applications. • Covers mechanical modeling and optimization of hybrid energy storage systems for performance improvement and focuses on hydrogen production, storage, and safety measures. • Explores the integration of IoT and global energy interaction technologies, highlighting their potential benefits in driving the transition toward a sustainable and resilient global energy system. • Explains different aspects of clean technologies such as batteries, fuel cells, ground energy storage, solar thermal system, and the role of green hydrogen in decarbonizing sectors like transportation and energy. • Showcases a clear idea of sustainable development using renewable energy, focusing on policymaking, challenges in transition from conventional to renewable energy, and future directions in energy sector. It is primarily written for senior undergraduates and graduate students, and academic researchers in the fields of mechanical engineering, production engineering, industrial engineering, and environmental engineering.
Low-Temperature Energy Systems with Applications of Renewable Energy investigates a wide variety of low-temperature energy applications in residential, commercial, institutional, and industrial areas. It addresses the basic principles that form the groundwork for more efficient energy conversion processes and includes detailed practical methods for carrying out these critical processes. This work considers new directions in the engineering use of technical thermodynamics and energy, including more in-depth studies of the use of renewable sources, and includes worked numerical examples, review questions, and practice problems to allow readers to test their own comprehension of the material. With detailed explanations, methods, models, and algorithms, Low-Temperature Energy Systems with Applications of Renewable Energy is a valuable reference for engineers and scientists in the field of renewable energy, as well as energy researchers and academics. Features end-of chapter review sections with questions and exercises for practical study and utilization. Presents methods for a great variety of energy applications to improve their energy operations. Applies real-world data to demonstrate the impact of low-temperature energy systems on renewable energy use today.
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
The text begins by discussing the sustainable buildings, energy efficient technologies, advanced materials, advances in renewable energy for building sector, green intelligent infrastructure, policies on sustainable infrastructure, and life cycle assessment. It further presents design considerations, challenges, and applications of net zero energy buildings with a global perspective. The book covers renewable energy technologies for energy-efficient buildings. This book: Discusses the importance of developing new materials for Energy and Heat Transfer Optimization in sustainable buildings and Life Cycle Assessment of Sustainable Building Materials. Investigates the city gas system, sustainable smart cities infrastructure, and Data Mining Techniques in Green Building for Evaluation of energy Cost, Grades and Adoption. Highlights the development and application Net Zero Energy Buildings, Energy Policies and Infrastructure Requirements, Building Performance Prediction & Optimization, and Energy Planning and Thermal Comfort in Buildings Presents renewable energy policies, Social, Economic, and Environmental Issues Associated with Sustainable Buildings, and Emerging Trends in Smart Green Building Technologies. Covers Energy-Efficient Urban Infrastructure, Earth-Air Heat Exchanger, and Retrofitting of existing buildings to achieve energy efficient buildings. It is primarily written for senior undergraduates, graduate students, and academic researchers in the fields of energy engineering, environmental science and engineering, materials science, mechanical engineering, and civil engineering.
Concentrating solar power (CSP) technology is poised to take its place as one of the major contributors to the future clean energy mix. Using straightforward manufacturing processes, CSP technology capitalises on conventional power generation cycles, whilst cost effectively matching supply and demand though the integration of thermal energy storage. Concentrating solar power technology provides a comprehensive review of this exciting technology, from the fundamental science to systems design, development and applications. Part one introduces fundamental principles of concentrating solar power systems. Site selection and feasibility analysis are discussed, alongside socio-economic and environmental assessments. Part two focuses on technologies including linear Fresnel reflector technology, parabolic-trough, central tower and parabolic dish concentrating solar power systems, and concentrating photovoltaic systems. Thermal energy storage, hybridization with fossil fuel power plants and the long-term market potential of CSP technology are explored. Part three goes on to discuss optimisation, improvements and applications. Topics discussed include absorber materials for solar thermal receivers, design optimisation through integrated techno-economic modelling, heliostat size optimisation, heat flux and temperature measurement technologies, concentrating solar heating and cooling for industrial processes, and solar fuels and industrial solar chemistry. With its distinguished editors and international team of expert contributors, Concentrating solar power technology is an essential guide for all those involved or interested in the design, production, development, optimisation and application of CSP technology, including renewable energy engineers and consultants, environmental governmental departments, solar thermal equipment manufacturers, researchers and academics. Provides a comprehensive review of concentrating solar power (CSP) technology, from the fundamental science to systems design, development and applications Reviews fundamental principles of concentrating solar power systems, including site selection and feasibility analysis and socio-economic and environmental assessments Provides an overview of technologies such as linear Fresnel reflector technology, parabolic-trough, central tower and parabolic dish concentrating solar power systems, and concentrating photovoltaic systems
In recent years, the interest of the scientific community towards efficient energy systems has significantly increased. One of the reasons is certainly related to the change in the temperature of the planet, which has increased by 0.76 °C with respect to preindustrial levels, according to the Intergovernmental Panel on Climate Change (IPCC), and is still increasing. The European Union considers it vital to prevent global warming from exceeding 2 °C with respect to pre-industrial levels, as it has been proven that this will result in irreversible and potentially catastrophic changes. These changes in climate are mainly caused by greenhouse gas emissions related to human activities, and can be drastically reduced by employing energy systems for the heating and cooling of buildings, as well as for power production, characterized by high efficiency levels and/or based on renewable energy sources. This Special Issue, published in the Energies journal, includes 13 contributions from across the world, including a wide range of applications such as hybrid residential renewable energy systems, desiccant-based air handling units, heat exchanges for engine WHR, solar chimney systems, and other interesting topics.
The text discusses energy-efficient vehicles as an essential element of sustainable transportation. The text highlights the social, economic, and environmental benefits associated with energy-efficient automobiles, which effectively solve the issue of greenhouse gas emissions, improve air quality, boost energy security, and promote zero-emission. The energy-efficient technologies for transportation, accessibility and safety of the transport system, environmental footprint, health impact, economic development, and social growth are the central theme of the book. It further presents future integrated mobility-energy systems and sustainability indicators. This book: Examines policies, challenges, and the latest developments in the field of sustainable mobility. Discusses the latest advances in the field of energy storage systems, batteries, image processing, obstacle identification, and automatic gear trains. Highlights the safety, security, and risk management related to sustainable transportation, covering zero emissions and sustainability indicators. Presents electric vehicle grid integration and infrastructure for e-vehicle charging. Aims to provide an overview of various aspects of EV, HEV, ITS, and vehicular network deployment design, encompassing the technological advancements, challenges, and opportunities associated with this rapidly evolving field. Understanding the transportation needs and preferences of youth populations in shaping transportation policy and promoting sustainable urban development to design transportation systems that are efficient, equitable, and environmentally sustainable. Synergize exploration related to the various properties and functionalities through extensive theoretical and numerical modeling present in the energy sector. This book is primarily written for senior undergraduate, graduate students, and academic researchers in fields including mechanical engineering, industrial engineering, automotive engineering, manufacturing engineering, and environmental engineering.
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.
Faced with an ever-growing resource scarcity and environmental regulations, the last 30 years have witnessed the rapid development of various renewable power sources, such as wind, tidal, and solar power generation. The variable and uncertain nature of these resources is well-known, while the utilization of power electronic converters presents new challenges for the stability of the power grid. Consequently, various control and operational strategies have been proposed and implemented by the industry and research community, with a growing requirement for flexibility and load regulation placed on conventional thermal power generation. Against this background, the modelling and control of conventional thermal engines, such as those based on diesel and gasoline, are experiencing serious obstacles when facing increasing environmental concerns. Efficient control that can fulfill the requirements of high efficiency, low pollution, and long durability is an emerging requirement. The modelling, simulation, and control of thermal energy systems are key to providing innovative and effective solutions. Through applying detailed dynamic modelling, a thorough understanding of the thermal conversion mechanism(s) can be achieved, based on which advanced control strategies can be designed to improve the performance of the thermal energy system, both in economic and environmental terms. Simulation studies and test beds are also of great significance for these research activities prior to proceeding to field tests. This Special Issue will contribute a practical and comprehensive forum for exchanging novel research ideas or empirical practices that bridge the modelling, simulation, and control of thermal energy systems. Papers that analyze particular aspects of thermal energy systems, involving, for example, conventional power plants, innovative thermal power generation, various thermal engines, thermal energy storage, and fundamental heat transfer management, on the basis of one or more of the following topics, are invited in this Special Issue: • Power plant modelling, simulation, and control; • Thermal engines; • Thermal energy control in building energy systems; • Combined heat and power (CHP) generation; • Thermal energy storage systems; • Improving thermal comfort technologies; • Optimization of complex thermal systems; • Modelling and control of thermal networks; • Thermal management of fuel cell systems; • Thermal control of solar utilization; • Heat pump control; • Heat exchanger control.