基于磁场传感阵列的压接型器件电流集中点非侵入式定位方法

doi:10.19595/j.cnki.1000-6753.tces.250806

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摘要压接型电力电子器件是高压大容量电能转换的核心器件,其内部电流分布均匀程度直接影响器件的运行可靠性。现有的压接型器件电流分布测量以内部安装电流传感器为主,而非侵入感知方法存在受通流汇流排影响及定位准确度不足的问题。因此,该文提出一种构建外部磁场传感器阵列实现器件内部电流分布集中点的非侵入式定位方法,使传感器敏感轴与汇流排电流平行布置,在最小化汇流排磁场影响的同时最大化器件磁场响应,并基于两组对称正交传感器的磁场强度比值建立正交基,最终利用比值线交点实现器件内部电流集中点的定位。实验结果表明,在120 mm直径的检测范围内,本方法的定位误差最大为11.1 mm,相对定位准确度达到90.7%,并利用该方法获取了实际压接型IGBT器件通态下的电流集中位置。

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关键词 ：压接型器件, 非侵入式感知, 电流集中点定位方法, 抗干扰方法

Abstract：Flexible high-voltage direct current (HVDC) transmission systems have become increasingly prevalent in modern power grids, particularly for long-distance bulk power transmission, integration of large-scale renewable energy sources, and interconnection of urban power networks. As the core switching component in these systems, press-pack insulated gate bipolar transistors (PP IGBTs) play a critical role in determining overall system reliability, power conversion efficiency, and operational stability. The development of non-invasive monitoring techniques capable of evaluating chip health status without modifying the original press-pack packaging structure holds significant importance for enhancing power system stability and enabling predictive maintenance strategies. This paper presents an innovative non-destructive testing methodology that utilizes an optimized external magnetic sensor array configuration to achieve localization of internal current density concentration points, thereby establishing a novel technical framework for condition monitoring of press-pack IGBTs.
The research begins with an analysis of the external magnetic field distribution characteristics exhibited by press-pack IGBT devices during operation. When energized, the internal current flow patterns generate a distinctive three-dimensional magnetic field distribution in the surrounding space. This magnetic signature demonstrates strong correlation with the operational health status of the semiconductor device, as aging or damage mechanisms produce measurable anomalies in the field distribution. By continuously monitoring spatial and temporal variations in the external magnetic field, it becomes possible to indirectly reconstruct and evaluate the internal current density distribution profile, enabling assessment of device condition. However, practical implementation faces significant challenges due to the complex electromagnetic environment in power electronic converters, where strong interference fields from busbars superimpose with target signals. To address this issue, this paper proposes a method that significantly suppresses external magnetic interference by optimizing sensor placement, while ensuring accurate measurement of magnetic field characteristics and minimizing busbar interference.
Secondly, this paper proposes a current concentration point localization method based on external magnetic field ratios. Theoretical derivation proves that under constant total current conditions, when a device fails, the external magnetic field is determined solely by the current amplitude and the coordinates of the current concentration point, and is directly proportional to the current amplitude. Therefore, the ratio of magnetic fields measured at two different positions can eliminate the influence of current amplitude, with the ratio depending only on the coordinates of the current concentration point. Based on this principle, two orthogonally arranged sensor arrays simultaneously measure the magnetic field to obtain two magnetic field ratio curves, whose intersection point represents the actual current concentration point. Subsequent finite element simulations verify the effectiveness of this method, demonstrating a maximum localization error of 8.9 mm and a relative accuracy of 92.6% within a 120 mm diameter detection range.
Finally, experimental results verify the feasibility of the proposed method. Anti-busbar interference tests demonstrate that the optimized sensor array reduces busbar interference to 7.4% of its original level. In customized metal conductor experiments where different conductor caps were used to control current distribution, results show a maximum positioning error of 11.1 mm and a relative positioning accuracy of 90.7% within a 120 mm diameter detection range. Subsequent experiments conducted on actual press-pack IGBT devices confirm the applicability of the proposed method for practical components.

Key words： Press pack devices non-invasive sensing localization method for current concentration points noise-immunity technique

收稿日期: 2025-05-13

PACS:

TM937

基金资助:国家自然科学基金青年科学基金项目（A类）（52225701）、国家资助博士后研究人员计划（C档）（GZC20230786）、中央高校基本科研业务费面上项目（2024MS006）和国家电网有限公司科技项目（SGJBDK00SBJS2310127）资助

通讯作者: 齐磊男,1978年生,教授,博士生导师,研究方向为先进输电技术及装备。E-mail：qilei@ncepu.edu.cn

作者简介: 沈弘男,1995年生,讲师,研究方向为柔性直流输电装备电磁兼容与状态感知。E-mail：shenhong@ncepu.edu.cn

引用本文:

沈弘, 崔浩, 钟俊帅, 陆远方, 齐磊. 基于磁场传感阵列的压接型器件电流集中点非侵入式定位方法[J]. 电工技术学报, 2026, 41(11): 3602-3611. Shen Hong, Cui Hao, Zhong Junshuai, Lu Yuanfang, Qi Lei. Method for Current Concentration Points in Press Pack Devices Based on Magnetic Field Sensor Arrays. Transactions of China Electrotechnical Society, 2026, 41(11): 3602-3611.

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