“advancements In Energy Storage Technologies: Powering The Next Generation” – Fast open-circuit voltage prediction and capacity estimation method of lithium-ion battery based on BP neural network
Open Access Policy Institutional Open Access Program Guidelines for Special Issues Editorial Process Research and Publication Ethics Article Processing Ethics Awards Statements
“advancements In Energy Storage Technologies: Powering The Next Generation”
All of his published articles are immediately available worldwide under an open access license. No specific permission is required to reuse all or part of an article published by , including images and tables. For articles published under the Creative Commons CC BY open access license, any part of the article may be reused without permission provided the original article is clearly cited. For more information, please see https:///openaccess.
Pdf) Review Of Strategies For Hybrid Energy Storage Management System In Electric Vehicle Application
Reference papers represent the most advanced research with significant potential for major impact in this field. A Feature Paper should be a substantial original article that includes several techniques or approaches, provides an outlook for future research directions, and describes possible applications of the research.
Papers are submitted at the individual invitation or recommendation of scientific editors and must receive positive feedback from reviewers.
Editor’s Choice articles are based on recommendations from scientific journal editors from around the world. The editors select a small number of recently published journal articles that they believe will be of particular interest to readers or important in a particular area of research. The aim is to provide a snapshot of some of the most exciting work published in the various research areas of the journal.
By Ibrahem E. Atawi Ibrahem E. Atawi Scilit Preprints.org Google Scholar 1, Ali Q. Al-Shetwi Ali Q. Al-Shetwi Scilit Preprints.org Google Scholar 2, 3, * , Amer M. Magableh Amer M. Magableh Scilit Preprints.org Google Scholar 4 and Omar H. Albalawi Omar H. Albalawi Scilit Preprints.org Google Scholar 5
Pdf) Advancements In Energy Storage Technologies For Smart Grid Development
Received: October 1, 2022 / Revised: November 9, 2022 / Accepted: December 22, 2022 / Published: December 30, 2022
The increased use of renewable energy sources (RES) and the intermittent nature of the energy they provide lead to several issues related to the stability, reliability and quality of electricity. In such cases, energy storage systems (ESS) offer a promising solution to such related RES issues. Therefore, several ESS techniques have been proposed in the literature to solve these problems; however, a single ESS does not meet all requirements for certain operations and has various trade-offs for overall system performance. This is mainly due to the limited capability of an ESS and its potential in terms of cost, lifetime, power and energy density, and dynamic response. In order to overcome the trade-off problem arising from the use of a single ESS system, a hybrid energy storage system (HESS) consisting of two or more ESSs is emerging as an effective solution. Recently, many studies have been considered to develop and propose different HESSs for different applications that show the great advantages of using multiple ESSs in one combined system. Although these individual methods are well documented, a comprehensive overview of HESS integrated RE has not been fully explored in the literature before. Therefore, as a new contribution to the literature, this study aims to review and analyze the importance and impact of HESS in the presence of renewable energy on sustainable development that will facilitate this emerging topic for researchers in the field. In this regard, the current scenario and recent trend of HESS in RES at the global level is discussed and analyzed, including a comparison with the main characteristics of ESS, along with the concept, design, classifications and detailed comparison of HESS. The new role of HESS was analyzed in terms of their advantages and application. The latest management and optimization methods of RES-related HESSs and their advantages and disadvantages are reviewed. Finally, open questions and new challenges in the direction of more efficient, sustainable and green energy are also highlighted here. All the highlighted insights of this review will hopefully lead to increased efforts towards the development of advanced HESS for future optimal operation of renewable energy.
Renewable energy; hybrid energy storage system; control and optimization; energy management; energy storage system; benefits and application; for and against; challenges; occasional nature
It is well known that environmental impacts, climate change and the polluting nature of today’s power systems have significantly increased the use of renewable energy sources (RES). In this regard, various RES, including hydro, solar, wind, wave, bioenergy, and geothermal energy, have been considered and used in many countries around the world [1, 2]. These sources, due to high energy requirements, are continuously developing and expanding. For example, the total installed capacity of RES increased by 11% and reached approximately 3146 GW by the end of 2021. The increase in RES capacity reached a new value of 315 gigawatts (GW) in 2021, representing a growth of 17% compared to previous years. Among all renewable energy sources, solar photovoltaic (PV) and wind energy have been the most successful forms of renewable energy (RE) development, contributing 90% of all new RE additions [1, 3]. Thus, solar PV and wind are two state-of-the-art RES that have also experienced widespread application globally in the last ten years, as shown in Figure 1 [1].
Commemorate World Energy Storage Day With 150+ Global Thought Leaders Driving Green Energy And Clean Transportation
Although photovoltaic and wind power plants have been widespread in the last decade, the intermittent availability of these sources can cause power oscillations, affecting the flexibility, stability, quality and reliability of power systems, as proved by the authors in Ref. [4]. In light of this, the authors in [5] showed that energy storage systems (ESS) can solve some of these RES problems. However, in [6], Matos et al. he clarified that the various ESS technologies currently in use are not sufficient to solve the problems related to RE systems. Moreover, as proven by the study conducted in [7], the authors proved that single ESS technology has limited features and cannot perform the desired operations or fulfill all the operational problems associated with RES. In the same way, the authors of [8] showed that each individual ESS has limitations that limit its field of application because an ideal application requires both high energy density and high power density. However, a single ESS technology cannot fulfill the desired operation due to its limited capability and potency in terms of lifetime, cost, energy and power density, and dynamic response, as concluded in [9]. Therefore, to overcome the operational limitations of a single ESS, a hybrid energy storage system (HESS) consisting of two or more ESSs is a promising solution to achieve optimal operation and integration of RES.
HESS consists of two or more heterogeneous storage technologies that have some kind of matching characteristics. This was done in order to take advantage of the positive aspects of each individual ESS technology, while at the same time restraining its disadvantages [10]. Therefore, lower cost, longer system lifetime, and better system efficiency are the most likely benefits due to hybridization’s ability to multitask and extend lifetime with less overall storage capacity [11]. In HESS, one storage is usually used for high dominant energy storage with low self-discharge rate and lower energy specific installation costs, and the other is used to manage high energy demand, transients and fast load changes. For example, some types of batteries contain features such as high specific energy, limited life cycle, low specific power, and low self-discharge units at a low cost per watt. On the other hand, supercapacitors (SC) show more specific power, less specific energy, longer lifetime, faster charging and higher self-discharge capacity [12, 13]. Therefore, a hybrid implementation, which includes a battery-SC combined together in one unit, can complement each other and have the advantages of both as a combined hybrid solution. Due to its homologous operational concept, wide availability and affordable initial cost, this combination has attracted great interest from researchers and developers in the industry [13, 14]. To achieve the best hybridization performance, efficient control and/or optimization strategies for energy management and other purposes are important for HESS [15]. However, the selection of control and optimization techniques and solving their shortcomings are still challenging [15, 16].
According to the literature, HESSs have been reviewed by various authors, especially for electric vehicle applications [13, 17, 18, 19]. In addition, a comprehensive overview of HESS energy control and management in electric vehicles has been previously investigated in [ 20 , 21 , 22 , 23 , 24 ]. Other review studies have focused on HESS applications for microgrids (MGs) [15, 25, 26], stand-alone PV systems [27], buildings [28] and stand-alone RE energy systems [29]. However, a comprehensive overview of recent ESS hybridization in renewable energy systems has not been fully discussed in the literature. In addition, all review studies only considered the topics of applications, power management, configuration, sizing, and topologies of converters. However, the recent progress of RES applications integrated into HESS and the benefits of grid-connected RES or stand-alone RES have not been sufficiently reviewed. Although many research works have recently been carried out and new forms of HESS in RE systems have been proposed which were not considered in the previous comprehensive review article. Furthermore, to improve the operation and performance of HESS in the presence of RE, new management and optimization methods
Next energy technologies, next generation web technologies, next energy technologies inc, next generation internet technologies, next generation communication technologies, next generation energy, next generation technologies, next generation technologies global inc, advancements in solar energy, new energy generation technologies, advancements in renewable energy, next generation sequencing technologies
