Abstract
The main purpose of the proposed system is to design a low-cost universal PV battery charger for electric vehicle application. The proposed system is integrated with a slope-compensated current controller which controls the charging current that corresponds to maximum power point of the PV module. As an interface converter, the proposed system consists of a buck converter to control the flow of the charging current and to find out the reference current Iref from the PV array at MPP. The battery control circuit is implemented by measuring the state of charge (SOC) of the battery, and an LCD display has been used to monitor the battery parameters. This proposed system acts as a smart and efficient PV battery charger for e-vehicles.
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References
Biswas S, Huang L, Vaidya V, Ravichandran K, Mohan N, Dhople SV (2016) Universal current-mode control schemes to charge Li-Ion batteries under DC/PV source. In: IEEE transactions on circuits and systems I: regular papers, Sept. 2016, vol 63(9), pp 15311542. https://doi.org/10.1109/TCSI.2016.2571218
Singh HK, Kumar N (2020) Current controlled charging scheme for off board electric vehicle batteries from solar PV array. In: 2020 7th International conference on signal processing and integrated networks (SPIN), Noida, India, pp 935–940. https://doi.org/10.1109/SPIN48934.2020.9071160
Maity A, Patra A, Yamamura N, Knight J (2011) Design of a 20 MHz DC-DC buck converter with 84 percent efficiency for portable applications. In: 2011 24th international conference on VLSIdesign, Chennai, India, pp 316–321. https://doi.org/10.1109/VLSID.2011.37
Achaibou N, Haddadi M, Malek A (2012) Modeling of lead acid batteries in PV systems. Energy Proc 18:538–544. ISSN 1876–6102. https://doi.org/10.1016/j.egypro.2012.05.065
Sant’Ana WC et al (2019) Implementation of automatic battery charging temperature compensation on a peak-shaving energy storage equipment. In: 2019 IEEE 15th Brazilian power electronics conference and 5th IEEE Southern power electronics conference (COBEP/SPEC), Santos, Brazil, pp 1−7. https://doi.org/10.1109/COBEP/SPEC44138.2019.9065670
Kondrath N, Kazimierczuk MK (2013) Slope compensation and relative stability of peak current-mode controlled PWM dc-dc converters in CCM. In: 2013 IEEE 56th international midwest symposium on circuits and systems (MWSCAS), Columbus, OH, USA, pp 477−480.https://doi.org/10.1109/MWSCAS.2013.6674689R
Sivakumar R, Ramprasath S, Babu PR (2015) Efficency and power packing density improvement for DC-DC boost converter by soft switching techniques. In: 2015 International conference on circuits, power and computing technologies [ICCPCT-2015], Nagercoil, India, pp 1–7. https://doi.org/10.1109/ICCPCT.2015.7159504
Wiesner, Diez R, Perilla G (2013) Design and implementation of a buck converter with MPPT for battery charge from solar module. In: 2013 Workshop on power electronics and power quality applications (PEPQA),Bogota, pp 1‒6. https://doi.org/10.1109/PEPQA.2013.6614938
Zhong J, Liu S (2011) Design of slope compensation circuit in peak-current controlled mode converters. In: 2011 International conference on electric information and control engineering, ICEICE 2011—Proceedings. IEEE, pp 1310–1313. https://doi.org/10.1109/ICEICE.2011.5778040
Hu Y, Wei Y, Wang J, Sun M (2016) Design of slope compensation for a high-efficiency high-current DC-DC converter. In: Proceedings 13th IEEE international conference solid-state integration circuit technology (ICSICT), October 2016, pp 1306–1308
Matwankar CS, Alam A (2019) Solar powered closed-loop current controlled DC-DC buck converter for battery charging application. In: 2019 International conference on vision towards emerging trends in communication and networking (ViTECoN), Vellore, India, pp 1–5. https://doi.org/10.1109/ViTECoN.2019.8899645
Radianto D, Dousoky GM, Shoyama M (2015) Design and implementation of fast PWM boost converter based on low cost microcontroller for photovoltaic systems. IECON 2015‒41st annual conference of the IEEE industrial electronics society, Yokohama, Japan, pp 002324–002328. https://doi.org/10.1109/IECON.2015.7392449
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Ramprasath, S., Abarna, R., Anjuka, G., Deva Priya, K., Iswarya, S., Krishnakumar, C. (2022). Performance Analysis of Slope-Compensated Current Controlled Universal PV Battery Charger for Electric Vehicle Applications. In: Subramani, C., Vijayakumar, K., Dakyo, B., Dash, S.S. (eds) Proceedings of International Conference on Power Electronics and Renewable Energy Systems. Lecture Notes in Electrical Engineering, vol 795. Springer, Singapore. https://doi.org/10.1007/978-981-16-4943-1_38
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