基于差分热阻的功率器件封装老化在线监测方法

魏晓光; 刘鉴辉; 唐新灵; 于克凡; 杜玉杰; 李玲

doi:10.13334/j.0258-8013.pcsee.242308

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基于差分热阻的功率器件封装老化在线监测方法

电力电子 | 更新时间：2026-02-01

- 基于差分热阻的功率器件封装老化在线监测方法
- An Online Monitoring Method of Power Devices Aging Based on Differential Thermal Resistance
- 中国电机工程学报 2025年第24期页码：9693-9702
- 作者机构：
  
  北京怀柔实验室, 北京市怀柔区,101499
- 作者简介：
- 基金信息：
- DOI：10.13334/j.0258-8013.pcsee.242308
  中图分类号：
- 纸质出版：2025
- 稿件说明：
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魏晓光, 刘鉴辉, 唐新灵, 等. 基于差分热阻的功率器件封装老化在线监测方法[J]. 中国电机工程学报, 2025,(24):9693-9702.

WEI Xiaoguang, LIU Jianhui, TANG Xinling, et al. An Online Monitoring Method of Power Devices Aging Based on Differential Thermal Resistance[J]. 2025, (24): 9693-9702.
魏晓光, 刘鉴辉, 唐新灵, 等. 基于差分热阻的功率器件封装老化在线监测方法[J]. 中国电机工程学报, 2025,(24):9693-9702. DOI： 10.13334/j.0258-8013.pcsee.242308.

WEI Xiaoguang, LIU Jianhui, TANG Xinling, et al. An Online Monitoring Method of Power Devices Aging Based on Differential Thermal Resistance[J]. 2025, (24): 9693-9702. DOI： 10.13334/j.0258-8013.pcsee.242308.

摘要

功率器件的封装老化是导致其失效的主要原因，近年来，封装老化的在线监测技术受到日益关注。功率器件封装的散热形式分为单面散热和双面散热，其中，焊料和键合线是单面散热封装的薄弱点，芯片-钼片接触界面是双面散热封装的薄弱点，封装薄弱点均为芯片直连界面。功率循环是评估器件封装可靠性的主要方法，通常将通态压降和结到壳热阻作为老化特征值，并通过在线监测老化特征值的变化获得封装的老化状态。然而，通态压降主要体现键合线老化，难以反映芯片焊料及芯片-钼片接触界面老化；芯片直连界面热阻在结到壳热阻中占比不足20%，结到壳热阻对芯片直连界面的老化敏感度低，传统监测方法无法准确反映器件封装老化。文中根据一维传热及瞬态热传导理论，提出差分式区域热阻定位法；通过对功率循环冷却过程中的结温序列进行向后差分，并结合加热功率转化为差分热阻，该方法可用于传热路径上任一封装结构老化的在线监测，并开发在线监测系统，首次在功率循环中实现了刚性压接器件芯片直连界面老化的在线监测。功率循环结果表明，差分式区域热阻定位法对芯片直连界面老化的敏感度是传统监测方法的4.80倍，与仿真得到的5.19倍接近，验证了仿真过程的正确性和器件封装老化新型监测方法的有效性。

Abstract

Packaging aging of power devices is a major cause of their failure. In recent years

online monitoring technology for packaging aging has received increasing attention. The thermal dissipation of power device packaging is divided into single-sided and double-sided cooling. Solder and bonding wires are the weak points of single-sided cooling packaging

while the chip-molybdenum interface is the weak point of double-sided cooling packaging. These weak points are all at the chip direct connection interface. Power cycling is the main method for evaluating the reliability of device packaging

primarily utilized by using on-state voltage drop and junction-to-case thermal resistance as aging characteristics which is applied to monitor package aging online. However

the on-state voltage drop mainly reflects bonding wire aging and cannot effectively indicate solder and chip-molybdenum interface aging. The thermal resistance of the chip direct connection interface accounts for less than 20% of the junction-to-case thermal resistance

making it less sensitive to aging. Traditional monitoring methods cannot accurately reflect packaging aging. This paper proposes a differential regional thermal resistance localization method based on one-dimensional heat transfer and transient thermal conduction theory

which can be used for online monitoring of the aging of any package structure along the heat transfer path by backward differencing the junction temperature sequences in the cooling process of the power cycle with the heating power converted into differential thermal resistance. This paper develops an online monitoring system

achieving the first online monitoring of chip direct connection interface aging in rigid press-pack devices during power cycling. Power cycling results show that the sensitivity of the differential regional thermal resistance localization method to chip direct connection interface aging is 4.80 times that of traditional monitoring methods

closely matching the simulation result of 5.19 times

and verifying the correctness of the simulation process and the effectiveness of the new monitoring method for device packaging aging.

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