Microchip’s new E-Fuse demonstrator board
To provide Battery Electric Vehicle (BEV) and Hybrid Electric Vehicle (HEV) designers with a faster and more reliable high-voltage circuit protection solution, Microchip Technology has announced the E-Fuse Demonstrator Board, enabled by SiC technology, available in six variants for 400–800V battery systems and with a current rating of up to 30A.
The E-Fuse demonstrator can detect and interrupt fault currents in microseconds, 100–500x faster than traditional mechanical approaches because of its high-voltage solid-state design. The fast response time substantially reduces peak short-circuit currents from tens of kilo-amps to hundreds of amps, which can prevent a fault event from resulting in a hard failure.
“The E-Fuse demonstrator provides BEV/HEV OEM designers with a SiC-based technology solution to jumpstart their development process with a faster, more reliable method for protecting power electronics,” said Clayton Pillion, vice president of Microchip’s silicon carbide business unit. “The E-Fuse solid-state design also alleviates long-term reliability concerns about electromechanical devices because there is no degradation from mechanical shock, arcing or contact bounce.”
With the E-Fuse demonstrator’s resettable feature, designers can easily package an E-Fuse in the vehicle without the burden of design-for-serviceability constraints. This reduces design complexities and enables flexible vehicle packaging to improve BEV/HEV power system distribution.
OEMs can accelerate the development of SiC-based auxiliary applications with the E-Fuse demonstrator because of the built-in Local Interconnect Network (LIN) communication interface. The LIN interface enables the configuration of the over-current trip characteristics without the need to modify hardware components, and it also reports diagnostic status.
The E-Fuse demonstrator leverages the ruggedness and performance of Microchip’s SiC MOSFET technology and PIC microcontrollers’ Core Independent Peripherals (CIPs) with a LIN-based interface. The companion components are automotive-qualified and yield a lower part count and higher reliability over a discrete design.