Analysis and Design of Hybrid Energy Storage SystemsJorge Garcia The most important environmental challenge today's society is facing is to reduce the effects of CO2 emissions and global warming. Such an ambitious challenge can only be achieved through a holistic approach, capable of tackling the problem from a multidisciplinary point of view. One of the core technologies called to play a critical role in this approach is the use of energy storage systems. These systems enable, among other things, the balancing of the stochastic behavior of Renewable Sources and Distributed Generation in modern Energy Systems; the efficient supply of industrial and consumer loads; the development of efficient and clean transport; and the development of Nearly-Zero Energy Buildings (nZEB) and intelligent cities. Hybrid Energy Storage Systems (HESS) consist of two (or more) storage devices with complementary key characteristics, that are able to behave jointly with better performance than any of the technologies considered individually. Recent developments in storage device technologies, interface systems, control and monitoring techniques, or visualization and information technologies have driven the implementation of HESS in many industrial, commercial and domestic applications. This Special Issue focuses on the analysis, design and implementation of hybrid energy storage systems across a broad spectrum, encompassing different storage technologies (including electrochemical, capacitive, mechanical or mechanical storage devices), engineering branches (power electronics and control strategies; energy engineering; energy engineering; chemistry; modelling, simulation and emulation techniques; data analysis and algorithms; social and economic analysis; intelligent and Internet-of-Things (IoT) systems; and so on.), applications (energy systems, renewable energy generation, industrial applications, transportation, Uninterruptible Power Supplies (UPS) and critical load supply, etc.) and evaluation and performance (size and weight benefits, efficiency and power loss, economic analysis, environmental costs, etc.). |
Common terms and phrases
accumulation algorithm analysis applications batteries BESS buck-boost converters calculated capacity charging compared comparison Component Conference connected considered converter cost CrossRef cycle DC bus demand density developed discharging distributed duty effect efficiency electrical Electron energy storage system fault Figure flow flywheel frequency fuel cell function grid HESS higher hybrid energy storage IEEE Trans improve increase integration interval Li-ion limit load losses maximum microgrids mode obtained operation optimization output peak performance Power Electron power system presented Proceedings proposed Pumped pumped storage PV plant ratio reduced reference renewable respectively scenarios scheme shipboard ships simulation Solar solution storage devices strategy supply switches Table technologies thermal topology traffic train Type units utility values vehicles voltage