As of my last update in September 2021, power electronics for wireless charging of electric vehicles (EVs) had been an area of active research and development. Since then, there might have been further advancements, but I can provide you with some of the key advancements up until that time:
Increased Efficiency: Researchers and engineers have been working on improving the overall efficiency of wireless charging systems for EVs. Efficiency gains help reduce energy losses during power transfer, making wireless charging more practical and cost-effective.
Higher Power Transfer Capability: Advancements in power electronics have allowed for higher power transfer capabilities in wireless charging systems. This enables faster charging rates, making it more convenient for EV owners and potentially reducing the charging time significantly.
Resonant Inductive Coupling: Inductive charging has been a widely adopted method for wireless EV charging. Resonant inductive coupling has been explored to improve the efficiency and extend the charging range. By tuning the frequency of the system to match the resonance frequency, higher power transfer efficiency can be achieved.
Dynamic Wireless Charging: One of the significant advancements has been in the field of dynamic wireless charging, where charging infrastructure is embedded into the road surface, and vehicles can charge while driving. This technology allows for continuous charging during long-distance travels without the need for frequent stops.
Smart Grid Integration: Power electronics advancements have also focused on better integration with smart grid systems. This integration allows for more efficient management of power flow, load balancing, and optimization of charging schedules, considering factors like grid demand and renewable energy availability.
Bi-Directional Charging: Power electronics advancements have enabled bi-directional charging capabilities. This means that EVs equipped with bidirectional charging technology can not only receive power but also supply power back to the grid or other devices when needed. This vehicle-to-grid (V2G) or vehicle-to-home (V2H) capability enhances the overall grid stability and enables the use of EVs as a mobile energy storage system.
Standardization Efforts: Standardization is crucial for the widespread adoption of any technology. Advancements in power electronics have also been complemented by efforts to establish common standards for wireless charging, ensuring interoperability and compatibility between different vehicles and charging stations.
Safety and Interference Mitigation: Power electronics have been improved to address safety concerns and electromagnetic interference issues related to wireless charging systems. Ensuring safe operation and minimal interference with other electronic devices is essential for the successful deployment of wireless charging technology.
Please note that the field of power electronics and wireless charging for EVs is rapidly evolving. It is likely that there have been further advancements beyond my last update, and I recommend checking the latest research and industry news for the most up-to-date information on this topic.