Pumped Hydro Energy Storage for Hybrid Systems takes a practical approach to present characteristic features, planning and implementation aspects, and techno-economic issues of PHES. It discusses the importance of pumped hydro energy storage and its role in load balancing, peak load shaving, grid stability and hybrid energy systems deployment. The book analyses the architecture and process description of different kinds of PHES, both established and upcoming. Different case studies of pumped hydro energy storage are discussed as well as the advantages and disadvantages of different applications. An essential read for students, researchers and engineers interested in renewable energy, hydropower, and hybrid energy systems. Provides a comprehensive overview of pumped-hydro storage systems and other uses of hydropower in hybrid energy systems Offers a practical approach that includes case studies to present in-depth information on project development and techno-economic challenges, including design, costs, performance and limitations of hybrid pumped hydro systems Explores pathways for hydropower energy storage systems optimization for better electricity generation

Pumped Hydro Energy Storage for Hybrid Systems takes a practical approach in its presentation of characteristic features, planning, implementation aspects, and techno-economic issues surrounding PHES. The book discusses the importance of pumped hydro energy storage and its role in load balancing, peak load shaving, grid stability and hybrid energy systems deployment. In addition, it analyzes the architecture and process description of different kinds of PHES, both stablished and upcoming, including technical specificities, performance characteristics, commercial maturity, cost, and relevant information on the typical components of PHES, such as hydraulic system of intakes, bottom outlets, hydraulic turbines, pumps, penstock, and electric generator. The authors look into the existing market structure for PHES and offer a techno-economic assessment according to two different concepts that consider capital costs, annual operations costs and benefits. Case studies of these analysis as well as of the systems themselves are examined, and the advantages and disadvantages of different applications are discussed. This book is a unique reference for energy researchers and energy engineers who look to design, develop, up-scale and optimize pumped hydro storage for better electricity generation. Academic and industry researchers specializing in cleaner production, regional sustainability, and sustainable development will also find here a helpful resource.

Thermal, Mechanical, and Hybrid Chemical Energy Storage Systems provides unique and comprehensive guidelines on all non-battery energy storage technologies, including their technical and design details, applications, and how to make decisions and purchase them for commercial use. The book covers all short and long-term electric grid storage technologies that utilize heat or mechanical potential energy to store electricity, including their cycles, application, advantages and disadvantages, such as round-trip-efficiency, duration, cost and siting. Also discussed are hybrid technologies that utilize hydrogen as a storage medium aside from battery technology. Readers will gain substantial knowledge on all major mechanical, thermal and hybrid energy storage technologies, their market, operational challenges, benefits, design and application criteria. Provide a state-of-the-art, ongoing R&D review Covers comprehensive energy storage hybridization tactics Features standalone chapters containing technology advances, design and applications

This book will provide the technical community with an overview of the development of new solutions and products that address key topics, including electric/hybrid vehicles, ultrafast battery charging, smart grids, renewable energy (e.g., solar and wind), peak shaving, and reduction of energy consumption. The needs for storage discussed are within the context of changes between the centralized power generation of today and the distributed utility of tomorrow, including the integration of renewable energy sources. Throughout the book, methods for quantitative and qualitative comparison of energy storage means are presented through their energy capacity as well as through their power capability for different applications. The definitions and symbols for energy density and power density are given and relate to the volume and weight of a given system or component. A relatively underdeveloped concept that is crucial to this text is known as the theory of Ragone plots. This theory makes possible the evaluation of the real amount of energy that can possibly release out of a given system, with respect to the level of power dependency chosen for the discharge process. From systems using electrochemical transformations, to classical battery energy storage elements and so-called flow batteries, to fuel cells and hydrogen storage, this book further investigates storage systems based on physical principles (e.g., gravitational potential forces, air compression, and rotational kinetic energy). This text also examines purely electrical systems such as superconductive magnets and capacitors. Another subject of analysis is the presentation of power electronic circuits and architectures that are needed for continuously controllable power flow to and from different storage means. For all systems described, the elementary principles of operation are given as well as the relationships for the quantified storage of energy. Finally, Energy Storage: Systems and Components contains multiple international case studies and a rich set of exercises that serve both students and practicing engineers.

Despite the urgent need for action, there is a widespread lack of understanding of the benefits of using green energy sources for not only reducing carbon emissions and climate change, but also for growing a sustainable economy and society. Future citizens of the world face increasing sustainability issues and need to be better prepared for energy transformation and sustainable future economic development. Cases on Green Energy and Sustainable Development is a critical research book that focuses on the important role renewable energy and energy efficiency play in energy transition and sustainable development and covers economic and promotion policies of major renewable energy and energy-efficiency technologies. Highlighting a wide range of topics such as economics, energy storage, and transportation technologies, this book is ideal for environmentalists, academicians, researchers, engineers, policymakers, and students.

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.

Power System Energy Storage Technologies provides a comprehensive analysis of the various technologies used to store electrical energy on both a small and large scale. Although expensive to implement, energy storage plants can offer significant benefits for the generation, distribution and use of electrical power. This is particularly important in renewable energy, which is intermittent in its supply. This book provides coverage of major technologies, such as sections on Pumped Storage Hydropower, Compressed-Air Energy Storage, Large Scale Batteries and Superconducting Magnetic Energy Storage, each of which is presented with discussions of their operation, performance, efficiency and the costs associated with implementation and management. Provides a description and analysis of various storage technologies, such as Pumped Storage Hydropower, Compressed-Air Energy Storage, Large Scale Batteries and Superconducting Magnetic Energy Storage Breaks down each storage type and analyzes their operation, performance, efficiency and costs Considers how each energy storage plant benefits the generation distribution and use of electric power