Electric Vehicle Battery Charger with Regenerative Braking and Photovoltaic Supply
Electric Vehicle Battery Charger with Regenerative Braking and Photovoltaic Supply
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Abstract
Considering the increasing use of electric vehicles
around the world and the problems that
their batteries present, this paper presents the
design and simulation of a device that allows
the use of the energy delivered by the electric
motor during the braking process. In addition,
to increase the autonomy of the vehicle, a PV
is located on the chassis to supply energy to the
engine or batteries. The device that captures
and delivers this energy is a bidirectional DCDC
converter located between the motor and
the battery, which is connected in parallel with
a Boost converter that operates as a follower of
the maximum power point to efficiently take advantage
of the energy delivered by the PV. The
simulation results show that the energy delivered
by the engine, PV and batteries can be used
in a good way and thus increase the efficiency
of the vehicle.
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Caruso, M., Di Tommaso, A., Imburgia, A., Longo, M., Miceli, R., Romano, P., . . . Viola, F. (2016). Economic evaluation of PV system for EV charging stations: Comparison between matching maximum orientation and storage system employment. proceeding of IEEE International Conference on Renewable Energy Research and Applications (ICRERA), (págs. 1179-1184).
Chaudhari, K., Ukil, A., Nandha , K., Manandhar, U., & Kumar, K. (2017). Hybrid Optimization for Economic Deployment of ESS in PV Integrated EV Charging Station. IEEE Transactions on Industrial Informatics, 106 -116.
Chen, Q., Liu, N., Hu, C., Wang, L., & Zhang, J. (2017). Autonomous Energy Management Strategy for Solid-State Transformer to Integrate PV-Assisted EV Charging Station Participating in Ancillary Service. Trans IEEE Transactions on Industrial Informatics, 258-269.
da Graça Carvalho, M., Bonifacio , M., & Dechamps, P. (2011). Building a low carbon society. Energy, 1842-1847.
Hassan, M., Vafamand, N., & Niknam, T. (2016). vT–S fuzzy model predictive speed control of electrical vehicles. Trans SA Transactions, 231-240.
Hassan, M., Vafamand, N., Niknam, T., Dragicevic, T., & Blaabjerg, F. (2017). Model-predictive control based on Takagi-Sugeno fuzzy model for electrical vehicles delayed model. Trans IET Electric Power Applications, 918-934.
Hernandez, J., Sutil, F., & Vidal, P. (2016). Protection of a multi-terminal dc compact node feeding electric vehicles on electric railway systems, secondary distribution networks, and PV systems. Turk. J. Elec, 3123-3143.
Jay, Z., Raihani, A., Elmagri, A., & Bouattane, A. (2017). Toward an approach to Improve MPPT Efficiency for PV System. proceeding of International Conference on Wireless Technologies, Embedded and Intelligent Systems (WITS), (págs. 1-5).
Khoucha, F., Benrabah, A., Herizi, O., Kheloui, A., & Benbouzid, M. (2013). An improved MPPT interleaved boost converter for solar electric vehicle application. proceeding of International Conference on Power Engineering, Energy and Electrical Drives, (págs. 1076-1081).
Krzysztof , U., Hrvoje, M., Neven , D., & Rodrigo, L. (2016). SDEWES 2014 – Sustainable Development of Energy, Water and Environment Systems. Journal of Cleaner Production, 1-11.
Lasheen, M., Kamel, A., Rahman, A., Abdel-Salam, A., & Ookawara, S. (2017). Adaptive reference voltage-based MPPT technique for PV applications. Trans IET Renewable Power Generation, 715-722.
LI, L., LI, X., Wang, X., Song, J., He, K., & Li, C. (2016). Analysis of downshift’s improvement to energy efficiency of an electric vehicle during regenerative braking. Trans Applied Energy, 125-137.
LI, W., Long, R., Chen, H., & Geng, J. (2017). A review of factors influencing consumer intentions to adopt battery electric vehicles. Trans Renewable and Sustainable Energy Reviews, 318-328.
Novosel, T., Ćosić, B., Pukšec, T., Krajačić, G., Duić, N., Mathiesen, B., Mustafa, M. (2015). Integration of renewables and reverse osmosis desalination e case study for the Jordanian energy system with a high share of wind and photovoltaics. Trans Energy, 270-278.
Peng, M., Liu, L., & Jiang, C. (2012). A review on the economic dispatch and risk management of the large-scale plug-in electric vehicles (phevs)- penetrated power systems. Renewable and Sustainable Energy Reviews, 1508 –1515.
Pietzcker, R., Stetter, D., Manger, S., & Luderer, G. (2014). Using the sun to decarbonize the power sector: The economic potential of photovoltaics and concentrating solar power. Trans Applied Energy, 704-720.
Reza, S., & Sharifian, E. (2015). A bidirectional 3-input DC-DC converter for electric vehicle applications. proceeding of 23rd Iranian Conference on Electrical Engineering, (págs. 1700-1704).
Sang-Keun, M., & Jin-O, K. (2017). Balanced charging strategies for electric vehicles on power systems. Trans Applied Energy, 44-54.
Wang, B., Xu, J., Cao, B., & Ning, B. (2017). Adaptive mode switch strategy based on simulated annealing optimization of a multi-mode hybrid energy storage system for electric vehicles. Trans Applied Energy, 596-608.
Wang, Z., Hong, J., Lui, P., & Zhang, L. (2017). Voltage fault diagnosis and prognosis of battery systems based on entropy and Z-score for electric vehicles. Trans Applied Energy, 289-302.
Zhang, B., Yang, Q., & Kezunovic, M. (2017). Placement of EV charging stations integrated with PV generation and battery storage. Proceeding Twelfth International Conference on Ecological Vehicles and Renewable Energies (EVER), 1-7.
