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Erschienen in:
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2022 | OriginalPaper | Buchkapitel

IOT-Monitored EV Charging Stations Using DC–DC Converter with Integrated Split Battery Energy System

verfasst von : M. Arun Noyal Doss, R. Brindha, A. Ananthi Christy, Viswanathan Ganesh

Erschienen in: Proceedings of International Conference on Power Electronics and Renewable Energy Systems

Verlag: Springer Singapore

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Abstract

This paper proposes a multiport converter-based idea of preparing a fully monitored UFEVCS. Different converters are utilized in order to test the achievement of ultrafast charging station. This charging station also seeks a factor of automation in battery management system. This battery management is accomplished by the use of IOT. A worldwide control project being designed to control different varieties of power flowing directions if anything unbalances in the system. The methods are thus simulated and therefore are being implemented on hardware. By the usage of CHB converter, the SOC of a system can balance itself. IOT-based battery management is carried in order to automate the charging station with much less efforts and more efficiency. The parameters calculated from the sensors are current (I), voltage (V) and power (W). These quantities from the sensors are transferred to things peak cloud. Thing speak cloud can be accessed from anywhere at any moment of time. Complete parameters of the battery of an EV can be uploaded to the user’s device

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Vorheriges Kapitel Modified Multiverse Optimization, Perturb and Observer Algorithm-Based MPPT for Grid-Connected Photovoltaic System
Nächstes Kapitel Implementation of TLBO Optimised PIλDμ Controller for LFC of Nonlinear Reheat Thermal Power System
Literatur
1.
2.
Haghbin S, Lundmark S, Alaküla M, Carlson O (2013) Grid-connected integrated battery chargers in vehicle applications: review and new solution. IEEE Trans Ind Electron 60(2):459–473CrossRef
3.
Lee J-Y, Chae H-J (2014) 6.6-kW onboard charger design using DCM PFC converter with harmonic modulation technique and two-stage dc/dc converter. IEEE Trans Ind Electron 61(3):1243–1252CrossRef
4.
Amjadi Z, Williamson SS (2010) Power-electronics-based solutions for plug-in hybrid electric vehicle energy storage and management systems. IEEE Trans Ind Electron 57(2):608–616CrossRef
5.
Yilmaz M, Krein PT (2013) Review of battery charger topologies, charging power levels, infrastructure for plug-in electric and hybrid vehicles. IEEE Trans Power Electron 28(5):2151–2169CrossRef
6.
7.
Battapothula G, Yammani C, Maheswarapu S (2019) Multi-objective optimal planning of FCSs and DGs in distribution system with future EV load enhancement. IET Electr. Syst. Transp. 9(3):128–139CrossRef
8.
Zou H, Manzie C, Neˇsi D (2015) PDE battery model simplification for charging strategy evaluation. c 978-1-4799-7862-5/15/$31.00 © 2015 IEEE
9.
Chellaswamy C, Nagaraju V, Muthammal R (2018) Solar and wind energy based charging station for electric vehicles. Int J Adv Res Electr Electron Instrum Eng 7(1):313–324
10.
Kang B, Gerbrand (2009) Battery materials for ultrafast charging and discharging. Ceder1 Nature 458
11.
Rishav M, Maity R, Shiva D (2019) Integration of renewable resources such as wind for electric vehicle and implementation of smart electric vehicle using IOT 8(1s4). ISSN: 2277–3878
12.
Vasiladiotis M, Rufer A (2015) A modular multiport power electronic transformer with integrated split battery energy storage for versatile ultrafast EV charging stations. IEEE Trans Ind Electron
Metadaten
Titel
IOT-Monitored EV Charging Stations Using DC–DC Converter with Integrated Split Battery Energy System
verfasst von
M. Arun Noyal Doss
R. Brindha
A. Ananthi Christy
Viswanathan Ganesh
Copyright-Jahr
2022
Verlag
Springer Singapore
Buch
Proceedings of International Conference on Power Electronics and Renewable Energy Systems

Print ISBN: 978-981-16-4942-4

Electronic ISBN: 978-981-16-4943-1

Copyright-Jahr: 2022

DOI
https://doi.org/10.1007/978-981-16-4943-1_62