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RESEARCH

Analysis and Design of an Overcurrent Protection Scheme Based on Parasitic Inductance of SiC MOSFET Power Module

Year: 2018 | Author: Keyao Sun | Paper: T3.4
Image of overcurrent detection circuit
Fig. 1. Overcurrent detection circuit.
The proposed overcurrent detection circuit is shown in Fig.1. Lp is the parasitic inductance of the power module between a Kelvin source and the power source. The overcurrent detection circuit which is implemented across the parasitic inductance contains two branches: the Cs, Rs branch for intense short circuit (SC) detection, and the Co, Ro, Lo branch for relatively slow overcurrent (OC) detection (except for instances of a short circuit, such as excessive current due to fault of load, etc). Voltage signal vo is the SC detection signal, while v’o is the OC detection signal. For each branch, two clamping diodes are used to protect the comparator. Dc, Rc, and Cc are used as a charging circuit to tune the sensitivity and response speed of the OC detection circuit. A detailed analysis and design process for each branch will be shown in the following sections.

Fig. 2 below (RsCs = 3e-6 to guarantee the linearity) shows the test result of drain current id and output voltage -vo. In order to show the matching between vo and id, vo is flipped here to positive. It is clear that the output voltage -vo nicely describes the drain current id during the rising edge. From the test result, the current value is around 1000 times the output voltage, so the parasitic inductance can be calculated.

The designed circuit includes two branches, which can not only detect an intense short circuit fault within 80 ns, but also detect a relatively slow overcurrent that could generate excessive heat and damage the system. The proposed scheme uses only a few simple and cheap components compared to other methods, and does not require any special techniques in a printed circuit board (PCB) (e.g., a Rogowski coil), or during the manufacture of the module (e.g., a current mirror). Other advantages of the proposed method include a lack of temperature dependency, wide sensing bandwidth and current range, very fast response speed, and high sensor density. A gate driver with embedded overcurrent protection is designed with a small profile (90 mm * 65 mm * 8 mm) and wide operation temperature range up to 105 °C.

Image of short circuit current and detection voltage signal.
Fig. 2. Short circuit current and detection voltage signal

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