Comparative Analysis of Energy Storage Technologies for Microgrids

Chehab, Mohamed Haikel; Ben Salah, Chokri; Falama, Ruben Zieba; Tlija, Mehdi; Rabhi, Abdelhamid

doi:10.1155/2023/6679740

Cited by 3 publications

(1 citation statement)

References 60 publications

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“…In Tunisia, the predominant electrical energy source is crude oil, except for certain countries relying on renewable sources [4]. Investing in renewables, specifically solar power, reduces reliance on fossil fuels, like oil, and enhances the country's energy independence [5][6][7][8]. Furthermore, embracing renewable energies, particularly solar power, contributes to mitigating CO2 emissions, offering both economic and environmental advantages [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Hybrid PVP/Battery/Fuel Cell Wireless Charging Station Using High-Frequency Optimized Inverter Technology for Electric Vehicles

Baccouche,

Chehab,

Ben Salah

et al. 2024

Preprint

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The design and integration of intelligent energy management systems in hybrid Electric Vehicle (EV) charging stations, leveraging Industry 4.0 and renewable energy sources, is crucial for advancing sustainability, efficiency, and technological development. This paper introduces a pioneering hybrid EV charging station that employs hybrid power sources, combining photovoltaic panels, a battery, and a fuel cell, each operating at 240V and 14A. Utilizing wireless power transfer technology, the system comprises five integral blocks: a power source, a boost converter, a High-Frequency (HF) inverter, transfer coils, and EV batteries. The optimization process involves two key stages: i) maximum power point tracking optimization of the boost converter, ensuring maximum power generation by varying the duty cycle between 10% and 90%, and ii) the HF phase employing a class-ϕ2 inverter at 30 MHz, synchronized with the resonant frequency of wireless power transfer coils. Control is executed through a digital signal processor card utilizing zero-voltage switching for efficient operations. This design enhances sustainability in EV charging solutions by optimizing power transfer through the use of hybrid sources.

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Section: Introductionmentioning

confidence: 99%

Hybrid PVP/Battery/Fuel Cell Wireless Charging Station Using High-Frequency Optimized Inverter Technology for Electric Vehicles

Baccouche,

Chehab,

Ben Salah

et al. 2024

Preprint

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Impact of Energy Storage Technologies on Grid-Connected Renewable Energy Systems

Al-Fatlawy,

Senthilkumar,

et al. 2024

E3S Web Conf.

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The inclusion of renewable energy into the grid causes issues thanks to the intermittent features of sources such as solar and wind. Energy storage technologies are crucial for grid reliability and efficiency. This study explores how batteries, pumped hydro, and flywheels affect grid-connected renewable energy systems. A thorough investigation is made on how energy storage mitigates difficulties such as voltage regulation, frequency control, and load balancing. Economics, environment, cost-benefit analysis, and sustainability are also considered. The analysis underlines the capacity of energy storage to ease the intermittency of renewable energy, while also emphasizing the technical, regulatory, and market constraints that must be solved for extensive deployment. The results imply that improvements in storage technologies are vital for reaching a more resilient, stable, and sustainable system driven by renewable energy.

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Hybrid PVP/Battery/Fuel Cell Wireless Charging Stations Using High-Frequency Optimized Inverter Technology for Electric Vehicles

Baccouche,

Chehab,

Ben Salah

et al. 2024

Energies

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The design and integration of intelligent energy management systems in hybrid electric vehicle (EV) charging stations, leveraging industry 4.0 and renewable energy sources, is crucial for advancing sustainability, efficiency, and technological development. The innovative hybrid EV charging station described in this study uses a combination of fuel cells, batteries, and solar panels that run at 14 amps a piece at 240 volts. The system consists of five essential components that work together to transfer power wirelessly: an EV battery bank, a boost converter, an HF inverter, transfer coils, and a power supply. Two crucial phases make up the optimization process. In phase 1, the boost converter’s maximum power point is tracked and optimized to generate the most power possible by varying the duty cycle between 10% and 90%. In phase 2, the HF uses a class ϕ2 inverter at 30 MHz to synchronize with the resonant frequency of wireless power transfer coils. Zero-voltage switching is used by a digital signal processor card to carry out control for effective operations. By utilizing hybrid sources to optimize power transmission, this design improves the sustainability of EV charging options.

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Comparative Analysis of Energy Storage Technologies for Microgrids

Cited by 3 publications

References 60 publications

Hybrid PVP/Battery/Fuel Cell Wireless Charging Station Using High-Frequency Optimized Inverter Technology for Electric Vehicles

Hybrid PVP/Battery/Fuel Cell Wireless Charging Station Using High-Frequency Optimized Inverter Technology for Electric Vehicles

Impact of Energy Storage Technologies on Grid-Connected Renewable Energy Systems

Hybrid PVP/Battery/Fuel Cell Wireless Charging Stations Using High-Frequency Optimized Inverter Technology for Electric Vehicles

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