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For Indian producers of multi-megawatt grid-connected ground-mounted solar photovoltaic power plants, it is crucial to understand that adopting the best Operations and Maintenance (O&M) practices is essential for optimizing energy output. The renewable energy industry in India has matured, and solar PV plants have seen a significant increase in installations over the past decade. These plants have contributed to the country's energy mix, ranging from rooftops, off-grid, to large-scale ground-mounted grid-connected plants. After installation and commissioning, a solar power plant has a life cycle of 25 to 30 years, and the O&M team plays a vital role in maintaining the plant's operating standards and ensuring guaranteed generation output figures. To maintain the quality of activity execution standards, some of the best industrial practices should be followed across installed portfolios. The first step is to identify plant losses at equipment and transmission line levels through careful observation and data-based approaches. Key performance indicators can be used to identify the nature and quantum of loss, and specific test procedures can be adopted for root cause identification and permanent issue resolution. It is crucial to ensure the serial implementation of corrections across plants and record improvements systematically through periodic maintenance activities. Following these procedures, checklists, and guidelines will help the team achieve the target optimum generation of the solar power plant, leading to increased investor confidence, reduced energy crises, sustained energy sources for longer periods, increased employment opportunities, and contributing towards clean green energy development across the country.
This handbook serves as a guide to deploying battery energy storage technologies, specifically for distributed energy resources and flexibility resources. Battery energy storage technology is the most promising, rapidly developed technology as it provides higher efficiency and ease of control. With energy transition through decarbonization and decentralization, energy storage plays a significant role to enhance grid efficiency by alleviating volatility from demand and supply. Energy storage also contributes to the grid integration of renewable energy and promotion of microgrid.
Recent Advances in Renewable Energy Technologies is a comprehensive reference covering critical research, laboratory and industry developments on renewable energy technological, production, conversion, storage, and management, including solar energy systems (thermal and photovoltaic), wind energy, hydropower, geothermal energy, bioenergy and hydrogen production, and large-scale development of renewable energy technologies and their impact on the global economy and power capacity. Technological advancements include resources assessment and deployment, materials performance improvement, system optimization and sizing, instrumentation and control, modeling and simulation, regulations, and policies.Each modular chapter examines recent advances in specific renewable energy systems, providing theoretical and applied aspects of system optimization, control and management and supports them with global case studies demonstrating practical applications and economical and environmental aspects through life cycle analysis. The book is of interest to engineering graduates, researchers, professors and industry professionals involved in the renewable energy sector and advanced engineering courses dealing with renewable energy, sources, thermal and electrical energy production and sustainability. - Focuses on the progress and research trends in solar, wind, biomass, and hydropower and geothermal energy production and conversion - Includes advanced techniques for the distribution, management, optimization, and storage of heat and energy using case studies
PHOTOVOLTAIC (PV) SYSTEM DELIVERY AS RELIABLE ENERGY INFRASTRUCTURE A practical guide to improving photovoltaic power plant lifecycle performance and output Photovoltaic (PV) System Delivery as Reliable Energy Infrastructure introduces a Preemptive Analytical Maintenance (PAM) for photovoltaic systems engineering, and the RepoweringTM planning approach, as a structured integrated system delivery process. A team of veteran photovoltaics professionals delivers a robust discussion of the lessons learned from mature industries—including PV, aerospace, utilities, rail, marine, and automotive—as applied to the photovoltaic industry. The book offers real-world “technical and fiscal” examples of the impact of photovoltaics to all stakeholders during the concept, specification, operations, maintenance, and RepoweringTM phases. In each chapter, readers will learn to develop RAMS specifications, reliability data collection, and tasks while becoming familiar with the inherent benefits of how these affect the cost of design and development, maintenance, spares, and systems operation. The authors also explain when and how to consider and implement RepoweringTM, plant upgrades and the considerations from concept through retirement and disposal of the plant. Readers will also find: A thorough introduction to Preemptive Analytical Maintenance (PAM), including systems engineering, lifecycle planning, risk management, risk assessment, risk reduction, as compared to the historic utility models, An in-depth treatment of the modern photovoltaic industry, including economic factors and the present endlessly evolving state of technology, Constructive discussions and application of systems engineering, including RAMS and System Engineering practices and solutions, Extensive explorations and application of data collection, curation, and analysis for PV systems, including advanced sensor technologies. Perfect for all new through to experienced photovoltaic design and specification engineers, photovoltaic plant owners, operators, PV asset managers and all interested stakeholders. Photovoltaic (PV) System Delivery as Reliable Energy Infrastructure will also earn a place in the libraries of utilities, engineering, procurements, construction professionals and students.
Building-integrated photovoltaics (BIPV) is an innovative technology offering a variety of building envelope solutions, materials, and colours for virtually any building surface. These BIPV products generate on-site renewable electricity, turning buildings from energy consumers to producers. BIPV is expected to play an indispensable role in the transition towards decarbonisation and energy resilience of cities, effectively reducing energy consumption and greenhouse gas emissions. Lack of knowledge and guidance on designing BIPV systems has hindered this technology's widespread adoption and creative applications. As a remedy, this guidebook presents best practices and decision-making processes for efficient and resilient architecture. Featuring more than 50 annotated reference drawings—roofs, solar shadings, rainscreen façades, curtain walls and double skin façades—and 24 international BIPV case studies, the guidebook provides building professionals with the technical knowledge and inspiration to implement BIPV technology in the built environment.
This study presents options to fully unlock the world’s vast solar PV potential over the period until 2050. It builds on IRENA’s global roadmap to scale up renewables and meet climate goals.
Growth in photovoltaic (PV) manufacturing worldwide continues to increase. In parallel, appropriate standards and certification schemes are being developed. During this period, clear guidance is crucial for integrating this technology into working practices of professionals in the building sector. This bestselling guide has become the essential tool for any installer, engineer and architect, offering guidance, and detailing every subject necessary for successful project implementation, from the technical design to the legal and market issues of PV installation. Beginning with resource assessment and an outline of the core components, this guide comprehensively covers system design, economic analysis, installation, operation and maintenance of PV systems. The book includes a free CD-ROM which contains essential software and additional material. The second edition has been fully updated to reflect the state-of-the-art in technology and concepts and includes: a new chapters on marketing and the history of PV; new information on the photovoltaic market; new material on lightning protection; a new section on building integrated systems; and new graphics, data, photos and software.
Photovoltaic generation is one of the cleanest forms of energy conversion available. One of the advantages offered by solar energy is its potential to provide sustainable electricity in areas not served by the conventional power grid. Optimisation of Photovoltaic Power Systems details explicit modelling, control and optimisation of the most popular stand-alone applications such as pumping, power supply, and desalination. Each section is concluded by an example using the MATLAB® and Simulink® packages to help the reader understand and evaluate the performance of different photovoltaic systems. Optimisation of Photovoltaic Power Systems provides engineers, graduate and postgraduate students with the means to understand, assess and develop their own photovoltaic systems. As such, it is an essential tool for all those wishing to specialise in stand-alone photovoltaic systems. Optimisation of Photovoltaic Power Systems aims to enable all researchers in the field of electrical engineering to thoroughly understand the concepts of photovoltaic systems; find solutions to their problems; and choose the appropriate mathematical model for optimising photovoltaic energy.