Comparative analysis of storage techniques for a grid with  renewable energy sources

Salkuti, Surender Reddy; Jung, Chan Mook

doi:10.14419/ijet.v7i3.12728

Cited by 17 publications

(12 citation statements)

References 36 publications

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“…, where the work focuses on the efect of ambient temperature on the mode and behavior of the BESS work, more precisely on the SOC and the internal cell temperature [64]. 23 shows that the BMS algorithm considers ambient temperature as a critical parameter and adjusts the charge and discharge parameters accordingly. Te algorithm continuously monitors the battery temperature and adjusts the charge and discharge current limits to keep the temperature within a safe range.…”

Section: Efect Of Ambient Temperature On Charging and Discharging Beh...mentioning

confidence: 99%

“…Tese studies focused on investment costs, life span, and price of units and neglected the specifc needs of MGs in terms of response time, recharge time, and operational safety. A comparison between the nature of batteries, their chemical compositions, and their manufacturing technology [23,24] helps understand such a technology using chemical equations, materials layers, energy density, etc. However, each study focused only on one type of batteries.…”

Section: Introductionmentioning

confidence: 99%

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Comparative Analysis of Energy Storage Technologies for Microgrids

Chehab,

Ben Salah,

Falama

et al. 2023

International Transactions on Electrical Energy Systems

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Nowadays, microgrids (MGs) are receiving a lot of attention. In an economical MG, the battery energy storage system (BESS) plays an important role. One of the biggest challenges in MGs is the optimal choice of the BESS that can lead to better performance of the MG, which will be more flexible, efficient, and effective than traditional power systems. In this paper, we present the modeling and simulation of different energy storage systems including Li-ion, lead-acid, nickel cadmium (Ni-Cd), nickel-metal hybrid (Ni-Mh), and supercapacitor (SC), for renewable energy applications, and more specifically for MGs. The results of simulation show that Li-ion batteries have a better response time than lead-acid batteries, Ni-Cd batteries, and Ni-Mh batteries and thus are more suitable for combination with supercapacitors. Li-ion batteries are the best option for fast-charging applications in MGs. The discharge phase ends with SOC ≤ ±94%, SOC ≤ ±95%, SOC = 95%, SOC < 95%, and SOC < 60%, respectively, for Li-ion, lead-acid, Ni-Cd, Ni-Mh, and supercapacitor. Moreover, the use of the battery management system (BMS) can significantly improve the performance of BESS, leading to higher levels of SOC and longer life span. The obtained results have shown that with an optimization algorithm for energy storage systems, more specifically for the battery-charging mode, the response time of BESSs can be further improved. The effect of ambient temperature has also been investigated on the functional capacities of the batteries. The obtained results demonstrated that extreme temperatures (80°C to −80°C) have a significant impact on battery performance and capacity, especially for Li-ion batteries, with a drop in capacity of up to 50% at −40°C. This highlights the importance of considering the ambient temperature in the design and operation of MGs. Overall, our study provides valuable insights into the optimal selection of BESS and the impact of ambient temperature on their performance, which can help in the development of more efficient and reliable MGs.

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Section: Efect Of Ambient Temperature On Charging and Discharging Beh...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Comparative Analysis of Energy Storage Technologies for Microgrids

Chehab,

Ben Salah,

Falama

et al. 2023

International Transactions on Electrical Energy Systems

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“…FES systems have low maintenance, no carbon emission, no toxic components, high cycle life, very fast response, high cycle efficiency (90-95%), very short discharge duration, and high power density [3,11,32,33]. However, FES suffers from idling losses when the FES is on standby.…”

Section: Mechanical Energy Storagementioning

confidence: 99%

“…SMES system has fast response time, very short discharge time, very high efficiency, its cycle life is not affected by the DoD, and a long lifetime [2,7,33,37]. However, SMES units have high capital costs, complicated cooling systems, high daily self-discharge rates (10-15%), and a negative environmental impact due to the strong magnetic field (see Tables 2-4).…”

Section: Electrical Energy Storagementioning

confidence: 99%

A Review of Energy Storage Technologies’ Application Potentials in Renewable Energy Sources Grid Integration

et al. 2020

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Renewable energy sources (RESs) such as wind and solar are frequently hit by fluctuations due to, for example, insufficient wind or sunshine. Energy storage technologies (ESTs) mitigate the problem by storing excess energy generated and then making it accessible on demand. While there are various EST studies, the literature remains isolated and dated. The comparison of the characteristics of ESTs and their potential applications is also short. This paper fills this gap. Using selected criteria, it identifies key ESTs and provides an updated review of the literature on ESTs and their application potential to the renewable energy sector. The critical review shows a high potential application for Li-ion batteries and most fit to mitigate the fluctuation of RESs in utility grid integration sector. However, for Li-ion batteries to be fully adopted in the RESs utility grid integration, their cost needs to be reduced.

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“…The issue of energy storage arises with the need to match the demand and supply of energy to individuals. The advent of electricity brought about more concern for the need for energy storage due to its prior nature of being used up when generated or converted to another form of energy [25]. However, new trends in energy show ways these generated energies could be stored and harnessed.…”

Section: Energy Storage Systems (Ess)mentioning

confidence: 99%

Energy Storage and Electric Vehicles: Technology, Operation, Challenges, and Cost-Benefit Analysis

Salkuti¹

2021

IJACSA

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With ever-increasing oil prices and concerns for the natural environment, there is a fast-growing interest in electric vehicles (EVs) and renewable energy resources (RERs), and they play an important role in a gradual transition. However, energy storage is the weak point of EVs that delays their progress. The world's EV industry is accelerating to faster adoption with appropriate incentives to the EV owners, policy support, and encouraging local manufacturing. The increasing demand for EV's has presented itself as an authentic alternative to internal combustion engines (ICE). The main feature of the RERs is their variability and intermittency. These drawbacks are overcome by integrating more than one renewable energy source including backup sources and storage systems. This paper presents various technologies, operations, challenges, and costbenefit analysis of energy storage systems and EVs.

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Comparative analysis of storage techniques for a grid with renewable energy sources

Cited by 17 publications

References 36 publications

Comparative Analysis of Energy Storage Technologies for Microgrids

Comparative Analysis of Energy Storage Technologies for Microgrids

A Review of Energy Storage Technologies’ Application Potentials in Renewable Energy Sources Grid Integration

Energy Storage and Electric Vehicles: Technology, Operation, Challenges, and Cost-Benefit Analysis

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