螺旋槽横磁触头间真空电弧跨槽过程的实验与仿真研究

doi:10.19595/j.cnki.1000-6753.tces.250288

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摘要螺旋槽横磁触头间真空电弧在运动过程中需要不断地跨过槽隙,跨槽过程导致的局部区域触头烧蚀以及槽隙填充对触头的开断性能有重要影响。该文对螺旋槽横磁触头间真空电弧的跨槽过程进行了针对性研究,准确地描述了跨槽过程中电弧的行为特征及形态演变规律,获取了电弧跨槽阶段的运动轨迹,并阐明了跨槽特性对电弧运动特性和触头表面烧蚀的影响机制。此外,通过仿真研究了跨槽过程中的电弧特性,对内部等离子体参数随时间的变化规律进行了详细分析。结果显示,当电弧运动至槽隙附近时,需要向槽隙对侧加热,电弧停滞并出现阴阳极射流分离现象,电弧运动速度明显降低,触头边缘烧蚀程度加剧。完成跨槽后,电弧重新集聚,继续沿触臂运动,运动速度加快。研究成果可为螺旋糟横磁触头槽隙结构设计和开断性能提升提供理论依据和技术参考。

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关键词 ：螺旋槽触头, 真空电弧, 电弧仿真, 电弧跨槽

Abstract：Vacuum circuit breakers are essential in medium/high voltage systems for the compact and eco-friendly design. Spiral slot transverse magnetic (TMF) contacts enhance arc control by slot-generated magnetic fields, but repeated arc crossing over slots induces localized erosion and slot filling, degrading performance.This study systematically investigates the slot-crossing process of vacuum arcs between spiral groove transverse magnetic (TMF) contacts, focusing on the dynamic evolution of arc morphology, plasma behavior, and their impacts on contact erosion and interruption performance. The slot-crossing process, where the arc transitions across spiral slots, critically influences contact ablation and arc motion stability. Understanding this process is essential for optimizing TMF contact design and enhancing the interruption capability of vacuum circuit breakers. By combining experimental observations with magnetohydrodynamic (MHD) simulations, this work elucidates the arc behavior during slot-crossing, including stagnation, anode-cathode jet separation, and velocity variations, providing insights into the interaction between arc dynamics and slot structures.
Experimental studies were conducted using a detachable vacuum chamber equipped with high-speed CCD cameras (20 000~22 000 frame per second) to capture arc morphology and voltage-current waveforms under peak currents ranging from 12 kA to 24 kA. The arc evolution during slot-crossing was categorized into four stages: initial expansion, unstable transition, motion, and diffusion. Key findings revealed that during slot-crossing, the arc transitions from a constricted mode to an anode jet mode, accompanied by a voltage drop of ~13 V. The arc stagnates near the slot edge, with its velocity decreasing by 80% (from ~300 m/s to 60 m/s), intensifying localized erosion. Higher peak currents prolonged the motion stage and stabilized arc morphology, reducing voltage fluctuations. Multi-angle imaging further quantified the arc trajectory, showing that slot-crossing accounted for a significant portion of the motion stage duration, highlighting its role in governing overall arc dynamics.
For simulation, a 2D transient MHD model was developed, coupling electromagnetic fields, plasma transport, and energy conservation equations. The model incorporated sheath layer effects, ionization, and heat flux interactions at electrode surfaces. Simulation results aligned with experimental observations, demonstrating ion density concentrations (up to 8.5×10²³ m^-3) and current density peaks (~10¹⁰ A/m²) near slot edges during slot-crossing. The sheath voltage at the cathode and anode surged to 29 V and 33 V, respectively, driving Joule heating (6.9×10¹⁰ W/m² at the anode and 4.3×10¹⁰ W/m² at the cathode) and material evaporation. The model validated the two-stage crossing mechanism: arc transitions from concentrated to anode-jet mode (voltage drop) and reverts post-crossing (voltage recovery), aligning with experimental observations.
The following conclusions are drawn: (1) The arc slot-crossing process comprises two distinct phases: a transition from a constricted mode (with voltage drop) to an anode jet mode, followed by re-constriction (voltage recovery), which reduces arc velocity by ~80% and intensifies groove-edge erosion due to prolonged localized heating. (2) Reducing the slot-crossing duration significantly enhances arc mobility, mitigates contact damage, and improves interruption performance by minimizing energy deposition in critical regions. (3) Optimizing groove geometry (e.g., slot width and number) is essential to balance electromagnetic force distribution and ablation resistance, providing critical theoretical and technical guidance for designing high-performance TMF contacts and advancing vacuum interrupters in alignment with sustainable energy goals.

Key words： Spiral slot contact vacuum arc arc simulation arc slot-crossing

收稿日期: 2025-02-24

PACS:

TM561.2

基金资助:国家自然科学基金资助项目（52177158）

通讯作者: 修士新男,1967年生,教授,博士生导师,研究方向为真空电弧理论及应用,电器试验检测技术、电器仿真分析及电器新产品研发等。E-mail: xsx@mail.xjtu.edu.cn

作者简介: 韦乐铭男,1996年生,博士研究生,研究方向为真空电弧理论及其应用。E-mail: wlm1996@stu.xjtu.edu.cn

引用本文:

韦乐铭, 修士新, 安珉昊, 王嘉欣, 林杏宇. 螺旋槽横磁触头间真空电弧跨槽过程的实验与仿真研究[J]. 电工技术学报, 2026, 41(3): 1012-1025. Wei Leming, Xiu Shixin, An Minhao, Wang Jiaxin, Lin Xingyu. Experimental and Simulation Study on the Vacuum Arc Crossing Process Between Spiral Slot Transverse Magnetic Contacts. Transactions of China Electrotechnical Society, 2026, 41(3): 1012-1025.

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https://dgjsxb.ces-transaction.com/CN/10.19595/j.cnki.1000-6753.tces.250288 https://dgjsxb.ces-transaction.com/CN/Y2026/V41/I3/1012

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