燃弧冲击下石墨烯改性铜钨合金触头的烧蚀损伤特性与增强机理

doi:10.19595/j.cnki.1000-6753.tces.250508

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摘要高压断路器触头操作过程中面临燃弧电流的冲击作用,使得铜钨合金材料容易发生烧蚀损伤问题。结合具有优异导热-机械性能的石墨烯材料,该文基于熔渗法制备了不同石墨烯和钨含量的改性铜钨合金触头,并通过设计的电弧烧蚀平台开展了改性材料的烧蚀损伤实验。结果发现,在电弧冲击过程中,纹影法拍摄显示石墨烯改性铜钨合金的烧蚀特征更少,石墨烯掺杂会显著地降低复合材料烧蚀时的阴/阳极与总质量损失。在石墨烯和钨的共同影响下,石墨烯掺杂质量分数为0.10%的CuW85改性材料表现最优,相较于未改性材料,其阴/阳极质量损失分别降低了43.1%和10.2%,总质量损失降低了19.9%。表面形貌测试结果表明,改性合金触头的孔洞、裂纹深度与液滴喷溅量明显减少,氧化物析出也有所降低。最后,考虑石墨烯对材料熔化后溶质扩散的抑制作用,建立了材料凝固演变过程的改进介观相场仿真模型,分析指出石墨烯通过促进溶质形成致密均匀的微观结构,减少了枝晶侧枝的过度生长,从而避免了表面裂纹扩张。该文结果可为石墨烯改性增强断路器触头性能提供一定的理论基础和实验依据。

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关键词 ：断路器触头, 石墨烯, 相场模拟, 电弧烧蚀

Abstract：Graphene is widely used as a reinforcing phase to improve the comprehensive properties of metal materials due to its excellent properties. Most of the existing studies discuss the strengthening effect of graphene on the copper-tungsten alloy contact materials from the perspective of the content of a single component. There is still a lack of research on the ablation resistance of copper-tungsten alloy composites under the combined influence of the graphene content and the tungsten content. Moreover, the internal action mechanism of graphene in enhancing the comprehensive properties of alloy materials is not clear. In this paper, a large current generation platform is built to simulate the current interrupted during the actual breaking process of the contact. The ablation characteristics of the contact materials after arc ablation are analyzed, and the phase field method is used to simulate the dendritic growth process during the ablation of the contact materials to explore the strengthening mechanism of graphene on copper-tungsten contacts.
Firstly, using the infiltration sintering method with a high-temperature sintered tungsten skeleton, CuW75, CuW80, and CuW85 alloy contact samples doped with 0%, 0.05%, 0.10%, and 0.15% graphene by mass were prepared. Each group of contact materials is subjected to a large current ablation experiment with a peak impact current of 52 kA for 25 times. Then, the optical schlieren method is used to observe the arcing process, and after the ablation experiment, a precision electronic balance is used to weigh the mass of the contact materials, and the mass loss is used to characterize the ablation resistance of the contact materials. Subsequently, an optical microscope and an electron microscope are used to observe the surface of the composite materials after ablation, and EDS energy spectrum analysis is carried out on the surface of the contact before and after ablation to explore the influence of the addition of graphene on the arc erosion characteristics of the copper-tungsten alloy at the microscale. Finally, a model of graphene-modified copper-tungsten alloy is established by the phase field method, and the dendritic growth process of the composite materials during the ablation process is simulated to explore the action mechanism of the addition of graphene and the tungsten content on the ablation resistance of the copper-tungsten alloy.
The experimental results show that the copper-tungsten alloy doped with graphene exhibits better ablation resistance. The doping of graphene can reduce the droplet sputtering amount of the contact materials during the arcing process, thereby reducing the mass loss of the copper-tungsten alloy composites. CuW75 and CuW80 perform best when doped with 0.05% graphene, while CuW85 performs best when doped with 0.10% graphene. Under the combined action of the graphene content and the tungsten content, the CuW85 alloy doped with 0.10% mass fraction of graphene has the least mass loss; at the microscale, the modified materials have fewer ablation characteristics on the surface compared with the unmodified materials after arc ablation, and the surface of the ablated materials contains more oxides; in the phase field simulation, both the graphene content and the tungsten content can inhibit the solute diffusion during dendritic growth, thus affecting the dendritic growth process of the alloy materials.
In summary, the experimental analysis leads to the following conclusions: (1) Both the graphene and the tungsten content jointly affect the arc ablation resistance of the modified alloy. With the increase of the graphene content, the mass loss of the modified materials shows a trend of first decreasing and then increasing. Among them, the CuW85 alloy doped with 0.10% mass fraction of graphene has the best performance, and its total mass loss is reduced by 19.9% compared with the unmodified materials. (2) The introduction of graphene can reduce the erosion characteristics of the copper-tungsten alloy contacts caused by the arcing impact at the microscale, thereby inhibiting the ablation damage of the contacts. (3) Graphene can enhance the ablation resistance of the modified alloy by hindering the solute diffusion and promoting the uniform and dense dendritic structure. The simulation calculation indicates that the addition of graphene can make the dendrites uniform and dense and reduce the degree of solute segregation on the surface of the ablated materials, thus inhibiting the expansion of surface cracks.

Key words： Circuit breaker contacts graphene phase field simulation arc burning

收稿日期: 2025-03-28

PACS:

TM561

基金资助:国家自然科学基金（52207153）和北京市自然科学基金（3242024, L241043）资助项目

通讯作者: 任瀚文男,1994年生,副教授,硕士生导师,研究方向为高电压与绝缘技术。E-mail：rhwncepu@ncepu.edu.cn

作者简介: 杨亚腾男,2002年生,硕士研究生,研究方向为断路器高性能触头材料设计。E-mail：yangyateng2002@163.com

引用本文:

任瀚文, 杨亚腾, 卞国荣, 丛浩熹, 李庆民. 燃弧冲击下石墨烯改性铜钨合金触头的烧蚀损伤特性与增强机理[J]. 电工技术学报, 2026, 41(7): 2433-2445. Ren Hanwen, Yang Yateng, Bian Guorong, Cong Haoxi, Li Qingmin. Ablative Damage Characteristics and Enhancement Mechanism of Graphene-Modified Copper-Tungsten Alloy Contacts under Arc Impact. Transactions of China Electrotechnical Society, 2026, 41(7): 2433-2445.

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https://dgjsxb.ces-transaction.com/CN/10.19595/j.cnki.1000-6753.tces.250508 https://dgjsxb.ces-transaction.com/CN/Y2026/V41/I7/2433

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