PTEE3028 Design of Electric Vehicle Charging System Syllabus:
PTEE3028 Design of Electric Vehicle Charging System Syllabus – Anna University Part time Regulation 2023
COURSE OBJECTIVES:
To know the charging station and standards
To learn the concepts of power converters in charging
To find the charging scheme in renewable based EV charging
To demonstrate the wireless power transfer technique
To design & simulate power factor correction circuits
UNIT I CHARGING STATIONS AND STANDARDS
Introduction-Charging technologies- Conductive charging, EV charging infrastructure, International standards and regulations – Inductive charging, need for inductive charging of EV, Modes and operating principle, Static and dynamic charging, Bidirectional power flow, International standards and regulations
UNIT II POWER ELECTRONICS FOR EV CHARGING
Layouts of EV Battery Charging Systems-AC charging-DC charging systems- Power Electronic Converters for EV Battery Charging- AC–DC converter with boost PFC circuit, with bridge and without bridge circuit – Bidirectional DC–DC Converters- Non-isolated DC–DC bidirectional converter topologies- Half-bridge bidirectional converter.
UNIT III EV CHARGING USING RENEWABLE AND STORAGE SYSTEMS
Introduction- – EV charger topologies , EV charging/discharging strategies – Integration of EV charging-home solar PV system , Operation modes of EVC-HSP system , Control strategy of EVCHSP system – fast-charging infrastructure with solar PV and energy storage.
UNIT IV WIRELESS POWER TRANSFER
Introduction – Inductive, Magnetic Resonance, Capacitive types. Wireless Chargers for Electric Vehicles – Types of Electric Vehicles – Battery Technology in EVs -Charging Modes in EVs – Benefits of WPT. – WPT Operation Modes – Standards for EV Wireless Chargers, SAE J2954, IEC 61980. ISO 19363
UNIT V POWER FACTOR CORRECTION IN CHARGING SYSTEM
Need for power factor correction- Boost Converter for Power Factor Correction, Sizing the Boost Inductor, Average Currents in the Rectifier and calculation of power losses
30 PERIODS
LAB COMPONENT: 30 PERIODS
1. Simulation and analysis for bi-directional charging V2G and G2V.
2. Design and demonstrate solar PV based EV charging station.
3. Simulate and infer wireless power charging station for EV charging.
4. Simulation of boost converter based power factor correction.
TOTAL: 30+30 = 60 PERIODS
COURSE OUTCOMES:
CO1: To illustrate various charging techniques and to know charging standards and regulations.
CO2: To demonstrate the working o DC-DC converters used for charging systems and principles
CO3: To illustrate the advantages of renewable system based charging systems
CO4: To demonstrate the principles of wireless power transfer.
CO5: To analyze the standards for wireless charging
CO6: To design and simulate boost converter based power factor correction.
REFERENCES:
1. Mobile Electric Vehicles Online Charging and Discharging, Miao Wang Ran Zhang Xuemin (Sherman) Shen, Springer 2016, 1st Edition.
2. Alicia Triviño-Cabrera, José M. González-González, José A. Aguado, Wireless Power Transferor Electric Vehicles: Foundations and Design Approach, Springer Publisher 1st Edition. 2020.
3. Nil Patel, Akash Kumar Bhoi, Sanjeevikumar Padmanaban, Jens Bo Holm-Nielsen, Electric Vehicles Modern Technologies and Trends. Springer Publisher 1st Edition, 2021.
4. Cable Based and Wireless Charging Systems for Electric Vehicles, Technology and control, management and grid integration, Rajiv Singh, Sanjeevikumar Padmanaban, Sanjeet Dwivedi, Marta Molinas and Frede Blaabjerg, IET 2021, 1st Edition.
5. Electric and Hybrid Electric Vehicles, James D Halderman, Pearson, 2022, 1st Edition.
6. Handbook of Automotive Power Electronics and Motor Drives, Ali Emadi, Taylor & Francis, 2005.