Requirements for vehicles that consume less energy and for smaller sized and lighter weight in-vehicle devices have been increasing. To address these issues, the industry is paying attention to power devices based on silicon carbide (SiC) or gallium nitride (GaN). When used in a vehicle, however, power devices must have superior high-temperature resistance and high-current characteristics, as well as excellent long-term reliability.
Silicon devices that are currently in wide use can sometimes reach temperatures of up to about 125 to 150°C when in operation. Because of their ability to deal with high current, SiC or GaN devices can operate in such high-temperature environments, even when temperatures soar to 200°C or more.
This encapsulation material has the following advantages:
1. The industry's highest heat-resistance characteristics contribute to the use of power devices in a heat-generating or high-temperature environment.
High-temperature resistance characteristics (glass transition temperature of the encapsulation material): up to 210°C (our conventional products*2: 170 to 180°C)
2. Superior long-term reliability contributes to improving the reliability of power devices.
In the following environmental resistance tests, neither cracks in the encapsulation material nor peeling from the leadframe and the power device element were observed.
- Thermal cycle test: -40 to 200°C, 1,000 cycles
- High-temperature shelf test: Left at 200°C for 3,000 hours
*1 As a semicondoctor encapsulation material for SiC or GaN power devices. Internal investigation as of October 1, 2015
*2 Our conventional product (CV4100 series)
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