Multifaceted Codesign for an Ultra High-Density, Double-Sided Cooled Traction Inverter Half Bridge Module

Roy, Aishworya

02 January 2024

The automotive sector finds itself undergoing a significant and substantial transformation, propelled by the pronounced proliferation of electric vehicles (EVs) and autonomous driving technologies. As the industry proactively adapts to embrace this, an increasingly pressing demand becomes evident for higher performance, reliability, sustainability, and speed. Semiconductor packages emerge as primary catalysts within this ongoing revolution, positioned squarely at the forefront to assume a critical and indispensable function in facilitating the realization of these fundamental objectives. Commercial vehicle manufacturers are taking steps to respond to these demands for sustainability and speed, the driving force in facilitating this being the shift from Si IGBTs to SiC MOSFETs. Silicon Carbide is an increasingly popular choice in inverter module fabrication for electric vehicle applications owing to its inherent characteristics such as reduced on resistance, higher blocking voltage, and higher temperature stability that enable high power density, increased efficiency, and speeds. This work focuses on developing and fabricating a high-density 1.7 kV, 300 A SiC MOSFET half-bridge power module tailored for a 280-320 kW, 2-level inverter configuration. Co-designed with the busbar and gate driver, the custom power module stresses efficient heat dissipation, minimized parasitic inductance, and a compact footprint. Key target parameters to achieve optimal performance include a Rdson below 20 mΩ, Rthjc under 0.2 K/W and a switching time below 20 ns. The proposed module features a double-sided cooling sandwiched structure, an integrated thermistor for health and degradation monitoring, and incorporates three Wolfspeed 3rd generation 1.7 kV, 18 mΩ devices per switch position. The simulated power loop inductance is 14.5 nH, the simulated parasitic resistance is 0.265 m, and the simulated junction-to-case thermal resistance is 0.12182 ℃/W. To keep the die temperature below 150 ℃, a cooling coefficient of 5500 W/m2 is necessary. / Master of Science / The automotive sector is in the midst of a major transformation, propelled by the noticeable spread of electric vehicles (EVs) and autonomous driving technologies. As the industry actively evolves to accommodate this, an increasingly pressing demand becomes apparent for higher performance, reliability, sustainability, and speed. Semiconductor packages are at the forefront of this transformation, playing a crucial role in achieving these goals. Commercial vehicle makers are taking steps to respond to these demands for sustainability and speed, the driving force for this being the shift from Si IGBTs to SiC MOSFETs. Silicon Carbide is an increasingly popular choice in inverter module fabrication for electric vehicle applications owing to its inherent characteristics such as reduced resistance, higher blocking voltage, and higher temperature stability that enable high power density, increased efficiency, and speeds. This study focuses on creating a compact and efficient power module for commercial electric vehicle applications. The designed module is capable of handling high power levels while remaining compact, thus prioritizing power density. This is carefully designed to ensure it cools down effectively, minimizes unnecessary energy losses, and has a small footprint. Certain key features, such as its commutation speed, current carrying capacity, and thermal and mechanical limitations, were also studied. A temperature sensor was incorporated to monitor its health and performance over time. Simulations were performed to validate that this module performs well in terms of its resistances in the electrical conduction path and the oath of heat dissipation.

SiC MOSFET

inverter module

electric vehicles

characterization

modeling

parametric study

parasitic impedances

Characterization and Modeling of High-Switching-Speed Behavior of SiC Active Devices

Chen, Zheng

28 January 2010

To support the study of potential utilization of the emerging silicon carbide (SiC) devices, two SiC active switches, namely 1.2 kV, 5 A SiC JFET manufactured by SiCED, and 1.2 kV, 20 A SiC MOSFET by CREE, have been investigated systematically in this thesis. The static and switching characteristics of the two switches have firstly been characterized to get the basic device information. Specific issues in the respective characterization process have been explored and discussed. Many of the characterization procedures presented are generic, so that they can be applied to the study of any future SiC unipolar active switches. Based on the characterization data, different modeling procedures have also been introduced for the two SiC devices. Considerations and measures about model improvement have been investigated and discussed, such as predicting the MOSFET transfer characteristics under high drain-source bias from switching waveforms. Both models have been verified by comparing simulation waveforms with the experimental results. imitations of each model have been explained as well. In order to capture the parasitic ringing in the very fast switching transients, a modeling methodology has also been proposed considering the circuit parasitics, with which a device-package combined simulation can be conducted to reproduce the detailed switching waveforms during the commutation process. This simulation, however, is inadequate to provide deep insights into the physics behind the ringing. Therefore a parametric study has also been conducted about the influence of parasitic impedances on the device's high-speed switching behavior. The main contributors to the parasitic oscillations have been identified to be the switching loop inductance and the device output junction capacitances. The effects of different parasitic components on the device stresses, switching energies, as well as electromagnetic interference (EMI) have all been thoroughly analyzed, whose results exhibit that the parasitic ringing fundamentally does not increase the switching loss but worsens the device stresses and EMI radiation. Based on the parametric study results, this thesis finally compares the difference of SiC JFET and MOSFET in their respective switching behavior, comes up with the concept of device switching speed limit under circuit parasitics, and establishes a general design guideline for high-speed switching circuits on device selection and layout optimization. / Master of Science

SiC MOSFET

SiC JFET

High switching speed

Parasitic impedances

Parametric study

Modeling

Characterization

Diferenční a pseudodiferenční kmitočtové filtry / Differential and pseudo-differential frequency filters

Sládok, Ondřej

January 2016

This thesis deals with fully differential and pseudo-differential frequency filters. Significant emphasis is placed on the characteristics of common-mode signal. Further, the text deals with the design issue of fully-differential structure and transformation of non-differential to pseudo-differential structures. In the thesis one non-differential structure, one fully-differential and three pseudo-differential structures are proposed, one of them working in current mode. The thesis also describes the analysis from the perspective of non-ideal properties of the active element of two circuit solutions, which is trying to find the optimal solution. In each case, functionality of new solutions is verified by simulations and in several cases also by experimental measurement.