Abstract
This paper proposes an integrated system for traction and battery charging of electric vehicles (EVs) with universal interface to the power grid. In the proposed system, the power electronics converters comprising the traction drive system are also used for the battery charging system, reducing the required hardware, meaning the integrated characteristic of the system. Besides, this interface is universal, since it can be performed with the three main types of power grids, namely: (1) Single-phase AC power grids; (2) Three-phase AC power grids; (3) DC power grids. In these three types of interfaces with the power grid, as well as in the traction drive operation mode, bidirectional operation is possible, framing the integration of this system into an EV in the context of smart grids. Moreover, the proposed system endows an EV with an on-board fast battery charger, whose operation allows either fast or slow battery charging. The main contributes of the proposed system are detailed in the paper, and simulation results are presented in order to attain the feasibility of the proposed system.
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Milberg, J., Schlenker, A.: Plug into the future. IEEE Power Energy Mag. 9(1), 56–65 (2011)
Gearhart, C., Breitenbach, A.: Connectivity and convergence: transportation for the 21st century. IEEE Electrification Mag. 2(2), 6–13 (2014)
Torres-Sanz, V., Sanguesa, J.A., Martinez, F.J., Garrido, P., Marquez-Barja, J.M.: Enhancing the charging process of electric vehicles at residential homes. IEEE Access 6, 22875–22888 (2018)
Teng, J.H., Liao, S.H., Wen, C.K.: Design of a fully decentralized controlled electric vehicle charger for mitigating charging impact on power grids. IEEE Trans. Ind. Appl. 53(2), 1497–1505 (2017)
Knezovic, K., Martinenas, S., Andersen, P.B., Zecchino, A., Marinelli, M.: Enhancing the role of electric vehicles in the power grid: field validation of multiple ancillary services. IEEE Trans. Transp. Electrification 3(1), 201–209 (2017)
Abousleiman, R., Scholer, R.: Smart charging: system design and implementation for interaction between plug-in electric vehicles and the power grid. IEEE Trans. Transp. Electrification 1(1), 18–25 (2015)
de Hoog, J., Alpcan, T., Brazil, M., Thomas, D.A., Mareels, I.: Optimal charging of electric vehicles taking distribution network constraints into account. IEEE Trans. Power Syst. 30(1), 365–375 (2015)
Vagropoulos, S.I., Kyriazidis, D.K., Bakirtzis, A.G.: Real-time charging management framework for electric vehicle aggregators in a market environment. IEEE Trans. Smart Grid 7(2), 948–957 (2015)
Kempton, W., Tomić, J.: Vehicle-to-grid power implementation: from stabilizing the grid to supporting large-scale renewable energy. J. Power Sources 144(1), 280–294 (2005)
Monteiro, V., Pinto, J.G., Afonso, J.L.: Operation modes for the electric vehicle in smart grids and smart homes: present and proposed modes. IEEE Trans. Veh. Technol. 65(3), 1007–1020 (2016)
Liu, C., Chau, K.T., Wu, D., Gao, S.: Opportunities and challenges of vehicle-to-home, vehicle-to-vehicle, and vehicle-to-grid technologies. Proc. IEEE 101(11), 2409–2427 (2013)
Monteiro, V., Exposto, B., Ferreira, J.C., Afonso, J.L.: Improved Vehicle-to-Home (iV2H) operation mode: experimental analysis of the electric vehicle as off-line UPS. IEEE Trans. Smart Grid 8(6), 2702–2711 (2017)
Kesler, M., Kisacikoglu, M.C., Tolbert, L.M.: Vehicle-to-grid reactive power operation using plug-in electric vehicle bidirectional offboard charger. IEEE Trans. Industr. Electron. 61(12), 6778–6784 (2014)
Hou, R., Emadi, A.: Applied integrated active filter auxiliary power module for electrified vehicles with single-phase onboard chargers. IEEE Trans. Power Electron. 32(3), 1860–1871 (2017)
Monteiro, V., Pinto, G., Afonso, J.L.: Experimental validation of a three-port integrated topology to interface electric vehicles and renewables with the electrical grid. IEEE Trans. Ind. Inform. 14(6), 2364–2374 (2018)
Ansari, J., Gholami, A., Kazemi, A., Jamei, M.: Environmental/economic dispatch incorporating renewable energy sources and plug-in vehicles. IET Gener. Transm. Distrib. 8(12), 2183–2198 (2014)
Rippel, W.: Integrated traction inverter and battery charger apparatus, US4920475A (1990)
Rippel, W., Cocconi, A.: Integrated motor drive and recharge system, US5099186A (1992)
Cocconi, A.: Combined motor drive and battery charger system, US5341075A (1994)
Yilmaz, M., Krein, P.T.: Review of battery charger topologies, charging power levels, and infrastructure for plug-in electric and hybrid vehicles. IEEE Trans. Power Electron. 28(5), 2151–2169 (2013)
Thimmesch, D.: An SCR inverter with an integral battery charger for electric vehicles. IEEE Trans. Ind. Appl. IA-21(4), 1023–1029 (1985)
Solero, L.: Nonconventional on-board charger for electric vehicle propulsion batteries. IEEE Trans. Veh. Technol. 50(1), 144–149 (2001)
Tang, L., Su, G.-J.: A low-cost, digitally-controlled charger for plug-in hybrid electric vehicles. In: 2009 IEEE Energy Conversion Congress and Exposition, pp. 3923–3929 (2009)
Haghbin, S., Lundmark, S., Alakula, M., Carlson, O.: Grid-connected integrated battery chargers in vehicle applications: review and new solution. IEEE Trans. Ind. Electron. 60(2), 459–473 (2013)
Chang, H.C., Liaw, C.M.: Development of a compact switched-reluctance motor drive for EV propulsion with voltage-boosting and PFC charging capabilities. IEEE Trans. Veh. Technol. 58(7), 3198–3215 (2009)
Subotic, I., Bodo, N., Levi, E.: An EV drive-train with integrated fast charging capability. IEEE Trans. Power Electron. 31(2), 1461–1471 (2016)
Liaw, C., Chang, H.: An integrated driving/charging switched reluctance motor drive using three-phase power module. IEEE Trans. Industr. Electron. 58(5), 1763–1775 (2010)
Kim, D.H., Kim, M.J., Lee, B.K.: An integrated battery charger with high power density and efficiency for electric vehicles. IEEE Trans. Power Electron. 32(6), 4553–4565 (2017)
Subotic, I., Bodo, N., Levi, E.: Single-phase on-board integrated battery chargers for EVs based on multiphase machines. IEEE Trans. Power Electron. 31(9), 6511–6523 (2016)
Chapman, D.: The Cost of Poor Power Quality. Power Quality Application Guide, no. 0b, p. 8 (2001). http://www.cda.org.uk
McGranaghan, M., Roettger, B.: Economic evaluation of power quality. IEEE Power Eng. Rev. 22(2), 8–12 (2002)
Acknowledgement
This work has been supported by COMPETE: POCI-01-0145-FEDER-007043 and FCT – Fundação para a Ciência e Tecnologia within the Project Scope: UID/CEC/00319/2013. This work has been supported by FCT within the Project Scope DAIPESEV – Development of Advanced Integrated Power Electronic Systems for Electric Vehicles: PTDC/EEI-EEE/30382/2017. Mr. Tiago Sousa is supported by the doctoral scholarship SFRH/BD/134353/2017 granted by the Portuguese FCT agency. This work is part of the FCT project 0302836 NORTE-01-0145-FEDER-030283.
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Sousa, T.J.C., Monteiro, V., Afonso, J.L. (2019). Integrated System for Traction and Battery Charging of Electric Vehicles with Universal Interface to the Power Grid. In: Camarinha-Matos, L., Almeida, R., Oliveira, J. (eds) Technological Innovation for Industry and Service Systems. DoCEIS 2019. IFIP Advances in Information and Communication Technology, vol 553. Springer, Cham. https://doi.org/10.1007/978-3-030-17771-3_31
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