期刊
IEEE TRANSACTIONS ON POWER ELECTRONICS
卷 38, 期 4, 页码 5296-5308出版社
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TPEL.2022.3227589
关键词
Electrode warpage; influence factors; lateral temperature difference; press pack IGBTs; thermomechanical coupling
Through finite element simulation with proper combination of boundary conditions, the influence of vertical and lateral temperature difference on electrode warpage was separated and analyzed. The lateral temperature difference was found to be the main reason for electrode warpage, which is different from the current perception, and provides the possibility to directly suppress electrode warpage. Furthermore, the role of the lateral temperature difference was analyzed by a simplified model, revealing that it could be decreased through pure thermal design rather than thermomechanical design. The electrode size and pedestal layout were discussed to alleviate the lateral temperature difference, and simulation results showed significant improvements in pressure and junction temperature distribution. Finally, the junction temperature distribution was measured to verify the root cause and the effectiveness of the improvement using the sequential V-CE(T) method.
The pressure and junction temperature distribution within press-pack insulated gated bipolar transistors had been proven uneven due to the thermomechanical coupling effect caused by electrode warpage. However, the root reason for the electrode warpage remains unclear, and therefore leads to confusion in optimization. In this article, the influence of vertical and lateral temperature difference on the electrode warpage is first separated and analyzed through the proper combination of boundary conditions in finite element simulation. The lateral temperature difference is found to be the main reason for the electrode warpage, which is different from the perception state of the art and provides the possibility to suppress the electrode warpage directly. Furthermore, the role of the lateral temperature difference is analyzed by a simplified model and it is found that the lateral temperature difference could be decreased by only pure thermal design rather than thermomechanical design. The electrode size and pedestal layout are discussed to alleviate the lateral temperature difference of the electrode and the simulation results also show great improvement in pressure and junction temperature distribution. Finally, the junction temperature distribution is measured by the sequential V-CE(T) method to verify the root reason and also the effectiveness of the improvement.
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