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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 manual aims to support the implementation of grid-connected rooftop photovoltaic (PV) projects in the Republic of Maldives. It provides information to assist utility engineers and rooftop solar service providers with the installation, operation, and maintenance of grid-connected solar PV systems, and reflects the latest industry best practices. It highlights the importance of observing safety requirements when dealing with all the elements of a new PV system.
This book focuses on the rapidly maturing solar photovoltaic (PV) industry, which is achieving an ever-increasing share of U.S. and global power production. There is a growing need for all stakeholders – owners, maintenance technicians, utilities, and installers – to fully understand the operations and maintenance of PV systems, and how to monitor and diagnose systems post installation. Recognizing this need, this book covers monitoring and diagnostic techniques and technologies, including how to identify the causes of poor performance, and measure and verify power production. Drawing on global case studies, it details how to achieve optimal PV power output in the field through an overview of basic electrical, the solar PV module and Balance of System, and processes and software for monitoring, measurement, and verification. It also provides an overview of the North American Board of Certified Energy Practitioner’s (NABCEP) new PV System Inspector credential, which will be outlined in the final chapter. Equipping the reader with the knowledge and confidence required to maximize the output of solar PV installations, Solar Photovoltaics Power Optimization will be an essential resource for PV practitioners and students.
The three-volume handbook showcases the state of the art in the use of concentrated sunlight to produce electricity, industrial process heat, renewable fuels, including hydrogen and low-carbon synthesis gas, and valuable chemical commodities. The handbook illustrates the value and diversity of applications for concentrating solar power to contribute to the expanding decarbonization of multiple cross-cutting energy sectors.Volume 1: Concentrating Solar Thermal Power, provides an overview of key technologies, principles, and challenges of concentrating solar power (CSP) as well as the use of concentrating solar thermal for process heating and district markets. The ten chapters of this volume provide the reader with the technical background on the solar resource for concentrating solar thermal, the principles and design of concentrating optics, and descriptions of state-of-the-art and emerging solar collector and receiver technologies, thermal storage and thermal-to-electric conversion and power cycles for CSP. It also contains a comprehensive summary of operations and maintenance requirements for CSP plants, and commercial CSP plants and markets around the world.Volume 2, Solar Thermochemical Processes and Products, covers the use of concentrated solar radiation as the heat source to drive endothermic chemical reactions to produce renewable fuels and valuable chemical commodities, equivalently storing solar energy in chemical bonds. The thermodynamic underpinnings of a number of approaches to produce fuel and results of demonstrations of solar thermochemical reactors for these processes at prototype scale are presented. Processes presented include thermochemical metal oxide reduction/oxidation cycles to split water and carbon dioxide solar chemical looping reformation of methane to produce synthesis gas, high temperature electrochemistry, and gasification of biomass. Research on the thermochemical storage for CSP and high temperature production of cement and ammonia to illustrate the use concentrated solar energy to produce valuable chemical products are also included.Volume 3 contains reprinted archival papers to support and supplement the material in Volumes 1 and 2. These papers provide background information on the economics and alternative use cases of CSP not covered in Volume 1, and expand on the material related to the chapter topics presented in Volume 2. Potential commercialization, such as prototype and demonstration projects, are highlighted. The papers are intended as a starting point for a more in-depth study of the topics.
Photovoltaic Solar Energy Conversion - Technologies, Applications and Environmental Impacts features comprehensive and up-to-date knowledge on the photovoltaic solar energy conversion technology and describes its different aspects in the context of most recent scientific and technological advances. It also provides an insight into future developments in this field by covering four distinct topics include "PV Cells and Modules", "Applications of PV Systems", "Life Cycle and Environmental Impacts" and "PV Market and Policies". An up-to-date reference book on the advances of photovoltaic solar energy conversion technology Describes different aspects of PV and PVT technologies in a comprehensive way Provides information on design, development, and monitoring of PV systems Covers applications of PV and PVT systems in the urban, industry, and agriculture sectors Features new concepts, environmental impacts, market and policies of the PV technology
Durability and Reliability of Polymers and Other Materials in Photovoltaic Modules describes the durability and reliability behavior of polymers used in Si-photovoltaic modules and systems, particularly in terms of physical aging and degradation process/mechanisms, characterization methods, accelerated exposure chamber and testing, module level testing, and service life prediction. The book compares polymeric materials to traditional materials used in solar applications, explaining the degradation pathways of the different elements of a photovoltaic module, including encapsulant, front sheet, back sheet, wires and connectors, adhesives, sealants, and more. In addition, users will find sections on the tests needed for the evaluation of polymer degradation and aging, as well as accelerated tests to aid in materials selection. As demand for photovoltaics continues to grow globally, with polymer photovoltaics offering significantly lower production costs compared to earlier approaches, this book will serve as a welcome resource on new avenues. - Provides comprehensive coverage of photovoltaic polymers, from fundamental degradation mechanisms, to specific case studies of durability and materials failure - Offers practical, actionable information in relation to service life prediction of photovoltaic modules and accelerated testing for materials selection - Includes up-to-date information and interpretation of safety regulations and testing of photovoltaic modules and materials
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.
The market and policy impetus to install increasingly utility-scale solar systems, or solar farms (sometimes known as solar parks or ranches), has seen products and applications develop ahead of the collective industry knowledge and experience. Recently however, the market has matured and investment opportunites for utility-scale solar farms or parks as part of renewable energy policies have made the sector more attractive. This book brings together the latest technical, practical and financial information available to provide an essential guide to solar farms, from design and planning to installation and maintenance. The book builds on the challenges and lessons learned from existing solar farms, that have been developed across the world, including in Europe, the USA, Australia, China and India. Topics covered include system design, system layout, international installation standards, operation and maintenance, grid penetration, planning applications, and skills required for installation, operation and maintenance. Highly illustrated in full colour, the book provides an essential practical guide for all industry professionals involved in or contemplating utility-scale, grid-connected solar systems.
Electric Utility Resource Planning: Past, Present and Future covers the balance of renewable costs, energy storage, and flexible backstop mechanisms needed in electric utility resource planning. In addition, it covers the optimization of planning methodologies and market design. The book argues that net load, ramping and volatility concerns associated with renewables call into question the validity of almost a century of planning approaches. Finally, it suggests that accounting for flexibility helps optimize the efficiency of the entire fleet of assets, minimizing costs and CO2 generation simultaneously, concluding that a flexible, independent backstop mechanism is needed, regardless of renewables or storage. Case studies provide a mix of hypothetical "what if" scenarios and analyses of real-life utility portfolios drawn from international examples. - Examines how resource planners and policy specialists can plan to incorporate renewable generation technologies, thus uniting considerations of technology, methodology, business and policy - Focuses on the reality of long-term decision-making and planning processes in working utilities - Reviews novel approaches towards resource planning that yield lower costs and CO2 - Emphasizes the need for flexible backstop mechanisms to maintain reliability