Summary
- Rapid growth in adoption of electric vehicles for consumer and commercial purposes
- EVs made up 17 percent of worldwide automobile sales in 2023
- Multilayer ceramic capacitors (MLCCs) commonly used in EV electronics and subsystems
- Key considerations and certifications for EV components discussed in whitepaper
- Capacitor requirements for specific applications in EV projects addressed
Article
The adoption of electric vehicles (EVs) is rapidly growing, with EVs making up 17 percent of worldwide automobile sales in 2023. This trend presents a challenge for EV design engineers and purchasing agents in finding cutting-edge components that can handle increasing temperatures, voltage, and power without sacrificing reliability, availability, and footprint. One commonly used component in EV electronics and subsystems is multilayer ceramic capacitors (MLCCs) due to their high temperature ratings, small size, and easy surface mount form factor.
To aid in the selection of automotive-grade capacitors for EV projects, this whitepaper discusses key considerations and certifications for EV components, common use cases in EV subsystems, and capacitor requirements for specific applications. By understanding the criteria for choosing the right capacitors, engineers and purchasing agents can ensure the success and reliability of their EV projects. It is essential to consider factors such as temperature ratings, voltage requirements, and power capabilities when selecting capacitors for EV applications.
The whitepaper provides insights into the challenges faced by EV designers and the importance of choosing appropriate components to meet the demands of increased electrification. With EVs becoming more prevalent in both consumer and commercial markets, the need for reliable and high-performance components is crucial. By focusing on the selection of capacitors that can withstand the harsh conditions of EV operation, engineers can ensure the longevity and efficiency of their EV systems.
In addition to discussing the technical aspects of capacitor selection, the whitepaper also addresses the certifications and standards that are essential for automotive-grade components. Certifications such as AEC-Q200 ensure that capacitors meet the stringent requirements for automotive applications, including reliability, durability, and quality. By choosing capacitors that are certified for automotive use, designers can have confidence in the performance and safety of their EV systems.
Overall, the whitepaper serves as a comprehensive guide for EV design engineers and purchasing agents in selecting the right capacitors for their projects. By understanding the key considerations and requirements for automotive-grade capacitors, stakeholders can make informed decisions that will contribute to the success of their EV systems. With the continued growth of the EV market, ensuring the reliability and efficiency of components such as capacitors is essential for the advancement of electric mobility.
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