2024

Vol.31 No.3

Editorial Office

Review

  • Journal of the Microelectronics and Packaging Society
  • Volume 25(3); 2018
  • Article

Review

Journal of the Microelectronics and Packaging Society 2018;25(3):21-30. Published online: Nov, 20, 2018

Improvement in Thermomechanical Reliability of Power Conversion Modules Using SiC Power Semiconductors: A Comparison of SiC and Si via FEM Simulation

  • Cheolgyu Kim1, Chulmin Oh2, Yunhwa Choi3, Kyung-Oun Jang4, Taek-Soo Kim1, †
    1Department of Mechanical Engineering, Korea Advanced Institute of Science and Technology (KAIST), 291, Daehak-ro, Yuseong-gu, Daejeon 34141, Korea 2Electronic Convergence Material & Device Research Center, Korea Electronic Technology Institute, Saenari-ro, Bundang-gu, Seongnam-si, Gyeonggi-do 13509, Korea 3JMJ Korea Co., Ltd., 102, Gilju-ro 425beon-gil, Bucheon-si, Gyeonggi-do 14487, Korea 4Power conversion, Fairchild Semiconductor Ltd., 55, Pyeongcheon-ro 850beon-gil, Bucheon-si, Gyeonggi-do 14487, Korea
Corresponding author E-mail: tskim1@kaist.ac.kr
Abstract

Driven by the recent energy saving trend, conventional silicon based power conversion modules are being replaced by modules using silicon carbide. Previous papers have focused mainly on the electrical advantages of silicon carbide semiconductors that can be used to design switching devices with much lower losses than conventional silicon based devices. However, no systematic study of their thermomechanical reliability in power conversion modules using finite element method (FEM) simulation has been presented. In this paper, silicon and silicon carbide based power devices with three-phase switching were designed and compared from the viewpoint of thermomechanical reliability. The switching loss of power conversion module was measured by the switching loss evaluation system and measured switching loss data was used for the thermal FEM simulation. Temperature and stress/strain distributions were analyzed. Finally, a thermal fatigue simulation was conducted to analyze the creep phenomenon of the joining materials. It was shown that at the working frequency of 20 kHz, the maximum temperature and stress of the power conversion module with SiC chips were reduced by 56% and 47%, respectively, compared with Si chips. In addition, the creep equivalent strain of joining material in SiC chip was reduced by 53% after thermal cycle, compared with the joining material in Si chip.

Keywords Power conversion module, silicon carbide (SiC), switching loss, thermal FEM simulation, thermomechanical reliability.