As electric vehicle (EV) adoption for both consumer and commercial purposes rapidly grows, so does the need for a more widespread, and faster, charging infrastructure. While we’ve seen vast improvements in charging technology in the last few years, as additional regulations on combustion vehicles are implemented and reliance on EVs increases, further EV charging innovations are needed. Currently, wireless charging is the newest EV charging technology evolving.
For wireless EV charging, inductive charging is used. This method of wireless power transfer works by creating a magnetic-resonance field between a transmitting pad on the ground that is physically connected to a power source and a receiving pad on the bottom of the EV that is connected to the vehicle’s battery (Figure 1).
Figure 1. An overview of a wireless charging configuration for an EV. Source.
But there are a number of challenges associated with developing this type of wireless charging solution for EVs including the following:
In our latest white paper, Making Electric Vehicle Wireless Charging a Reality, we focus on how you can address these challenges by selecting resonant capacitors designed to ensure the reliability and efficiency of your wireless chargers’ LC compensation network. While resonant capacitor applications today are mainly dominated by film capacitor technology, in this paper, we highlight several reasons multilayer ceramic capacitors (MLCCs), and particularly MLCCs built with our proprietary ceramics, are a much better alternative. We also explore several off-the-shelf and custom resonant capacitor options from Knowles Precision Devices that can help you make your wireless EV charging technology a reality.
Download our new white paper, Making Electric Vehicle Wireless Charging a Reality, to learn more about working with Knowles Precision Devices to bring stability and reliability to your wireless EV charging application from the very beginning.
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