IGBT功率模块结构参数对回流翘曲与应力分布的影响*

doi:10.16257/j.cnki.1681-1070.2026.0043

摘要/Abstract

摘要： 绝缘栅双极型晶体管（IGBT）功率模块是实现新能源汽车中能量转换的核心器件。然而，模块内部的不对称结构和各材料间热膨胀系数（CTE）的显著失配使得IGBT功率模块在回流焊后易产生翘曲和应力集中，从而导致其性能与使用寿命严重下降。为探究影响IGBT功率模块翘曲和应力的因素，基于Ansys Workbench建立IGBT功率模块的有限元模型，结合“单元生死”建模技术与焊料的Anand黏塑性本构模型，对不同底板厚度、直接覆铜（DBC）基板陶瓷层与铜层厚度以及DBC基板间距条件下模块的翘曲和应力进行对比分析。结果表明，IGBT功率模块的最大翘曲随底板厚度、DBC铜层厚度及DBC基板间距的增加而减小；底板的最大翘曲则随底板厚度和DBC陶瓷层厚度的增加而减小；底板厚度、DBC陶瓷层厚度、铜层厚度和DBC基板间距对焊料层的最大应力影响不显著。增加底板厚度可显著抑制IGBT功率模块翘曲，DBC陶瓷层厚度是影响模块翘曲的最关键因素。研究结果可为降低IGBT功率模块生产成本、提升产品良率提供参考。

关键词: 回流焊, 翘曲, 应力, 有限元仿真, IGBT功率模块

Abstract: Insulated-gate bipolar transistor (IGBT) power modules serve as the core components for energy conversion in new energy vehicles. However, due to the asymmetric internal structure of the modules and the significant mismatch in the coefficients of thermal expansion (CTE) among different materials, IGBT power modules are prone to warpage and stress concentration after the reflow soldering process, leading to severe degradation of their performance and service life. To investigate the factors affecting the warpage and stress of IGBT power modules, a finite element model of the IGBT power module is established based on Ansys Workbench. By integrating the "element birth and death" modeling technique and the Anand viscoplastic constitutive model for solder, a comparative analysis is conducted on the warpage and stress of the modules under different conditions, including baseplate thickness, the thicknesses of the ceramic layer and copper layers of the direct-bonded copper (DBC) substrate, and the spacing between adjacent DBC substrates. The results show that the maximum warpage of IGBT power modules decreases with increasing baseplate thickness, DBC copper layer thickness and DBC substrate spacing. The maximum warpage of the baseplate decreases with increasing baseplate thickness and DBC ceramic layer thickness. The baseplate thickness, DBC ceramic layer thickness, copper layer thickness and DBC substrate spacing have no significant effect on the maximum stress of the solder layer. Increasing the baseplate thickness can significantly inhibit the warpage of the IGBT power module, and the thickness of the DBC ceramic layer is the most critical factor affecting the warpage of the modules. The research results provide a reference for reducing the production cost and improving the product yield of IGBT power modules.

Key words: reflow soldering, warpage, stress, finite element simulation, IGBT power module

中图分类号:

TN305.94

常茹夏，朱琳，高静怡，黄明亮. IGBT功率模块结构参数对回流翘曲与应力分布的影响^*[J]. 电子与封装, 2026, 26(4): 040206 .

CHANG Ruxia, ZHU Lin, GAO Jingyi, HUANG Mingliang. Effects of IGBT Power Module Structural Parameters on Reflow Warpage and Stress Distribution[J]. Electronics & Packaging, 2026, 26(4): 040206 .

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中国电子学会电子制造与封装技术分会会刊

中国半导体行业协会封测分会会刊

无锡市集成电路学会会刊

IGBT功率模块结构参数对回流翘曲与应力分布的影响^*

Effects of IGBT Power Module Structural Parameters on Reflow Warpage and Stress Distribution

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