Operational Three-Mode (3M) Algorithm for a Bi-Directional PEV Charger in G2V, V2H, and V2G Applications
Electric vehicles (EVs) are widely recognized as one of the most effective strategies for reducing oil consumption and greenhouse gas emissions, establishing them as a key option for the future of road transportation. The widespread adoption of EVs is expected to have a profound societal impact, inf...
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| Published in | 2025 13th International Electrical Engineering Congress (iEECON) pp. 1 - 5 |
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| Main Authors | , , |
| Format | Conference Proceeding |
| Language | English |
| Published |
IEEE
05.03.2025
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| Subjects | |
| Online Access | Get full text |
| DOI | 10.1109/iEECON64081.2025.10987629 |
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| Abstract | Electric vehicles (EVs) are widely recognized as one of the most effective strategies for reducing oil consumption and greenhouse gas emissions, establishing them as a key option for the future of road transportation. The widespread adoption of EVs is expected to have a profound societal impact, influencing various aspects of human life. A key advantage of EVs is their battery module, which offers a higher capacity compared to other devices. This high-capacity battery can also function as an energy storage system (ESS) for homes when connected to a charger. This paper presents the operational modes of a single-phase bi-directional plug-in electric vehicle (PEV) charger designed for G2V/V2H/V2G applications. The proposed system employs a bi-directional converter to facilitate two-way power flow between the home and the vehicle. The topology includes two stages: 1) a synchronous DC-DC converter and 2) a full-bridge AC-DC converter. The system operates in three modes: battery charging, energy backup, and grid-connected modes. Designed for a 7.7 kVA single-phase onboard charger, the system's feasibility is verified through simulations. |
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| AbstractList | Electric vehicles (EVs) are widely recognized as one of the most effective strategies for reducing oil consumption and greenhouse gas emissions, establishing them as a key option for the future of road transportation. The widespread adoption of EVs is expected to have a profound societal impact, influencing various aspects of human life. A key advantage of EVs is their battery module, which offers a higher capacity compared to other devices. This high-capacity battery can also function as an energy storage system (ESS) for homes when connected to a charger. This paper presents the operational modes of a single-phase bi-directional plug-in electric vehicle (PEV) charger designed for G2V/V2H/V2G applications. The proposed system employs a bi-directional converter to facilitate two-way power flow between the home and the vehicle. The topology includes two stages: 1) a synchronous DC-DC converter and 2) a full-bridge AC-DC converter. The system operates in three modes: battery charging, energy backup, and grid-connected modes. Designed for a 7.7 kVA single-phase onboard charger, the system's feasibility is verified through simulations. |
| Author | Jindapetch, Nattha Sengchuai, Kiattisak Rojchaya, Sittisak |
| Author_xml | – sequence: 1 givenname: Sittisak surname: Rojchaya fullname: Rojchaya, Sittisak email: sittisak.r@rmutsv.ac.th organization: Prince of Songkla University,Faculty of Engineering,Department of Electrical & Biomedical Engineering,Songkhla,Thailand – sequence: 2 givenname: Nattha surname: Jindapetch fullname: Jindapetch, Nattha email: nattha.s@psu.ac.th organization: Prince of Songkla University,Faculty of Engineering,Department of Electrical & Biomedical Engineering,Songkhla,Thailand – sequence: 3 givenname: Kiattisak surname: Sengchuai fullname: Sengchuai, Kiattisak email: kiattisak.se@psu.ac.th organization: Prince of Songkla University,Faculty of Engineering,Department of Electrical & Biomedical Engineering,Songkhla,Thailand |
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| SubjectTerms | Batteries bi-directional charger Bidirectional control grid-to-vehicle (G2V) Rectifiers Road transportation Smart homes Topology Uninterruptible power systems Vehicle-to-grid vehicle-to-grid (V2G) vehicle-to-home (V2H) Voltage control |
| Title | Operational Three-Mode (3M) Algorithm for a Bi-Directional PEV Charger in G2V, V2H, and V2G Applications |
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