A plasma energy deposition based model for power cable bellows discharge

IF 1 4区 工程技术 Q4 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Chong Xu, Penbo Wang, Fan Yang, Shaohua Wang, Junping Cao, Xin Wang
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引用次数: 0

Abstract

Purpose This paper aims at building a discharge model for the power cable bellows based on plasma energy deposition and analyzing the discharge ablation problem. Design/methodology/approach Aiming at the multiphysical mechanism of the discharge ablation process, a multiphysical field model based on plasma energy deposition is established to analyze the discharge characteristics of the power cable bellows. The electrostatic field, plasma characteristics, energy deposition and temperature field are analyzed. The discharge experiment is also carried out for result validation. Findings The physical mechanism of the bellows ablative effect caused by partial discharge is studied. The results show that the electric field intensity between the aluminum sheath and the buffer layer easily exceeds the pressure resistance value of air breakdown. On the plasma surface of the buffer layer, the electron density is about 4 × 1,019/m3, and the average temperature of electrons is about 3.5 eV. The energy deposition analysis using the Monte Carlo method shows that the electron range in the plasma is very short. The release will complete within 10 nm, and it only takes 0.1 s to increase the maximum temperature of the buffer layer to more than 1,000 K, thus causing various thermal effects. Originality/value Its physical process involves the distortion of electric field, formation of plasma, energy deposition of electrons, and abrupt change of temperature field.
基于等离子体能量沉积的电力电缆波纹管放电模型
目的建立基于等离子体能量沉积的电力电缆波纹管放电模型,并对放电烧蚀问题进行分析。摘要针对放电烧蚀过程的多物理场机理,建立了基于等离子体能量沉积的多物理场模型,分析了电力电缆波纹管的放电特性。分析了静电场、等离子体特性、能量沉积和温度场。为验证结果,还进行了放电实验。结果研究了局部放电引起波纹管烧蚀效应的物理机理。结果表明:铝护套与缓冲层之间的电场强度容易超过空气击穿的耐压值;在缓冲层等离子体表面,电子密度约为4 × 1019 /m3,电子平均温度约为3.5 eV。用蒙特卡罗方法进行能量沉积分析表明,等离子体中的电子范围很短。释放将在10 nm内完成,并且只需要0.1 s就可以将缓冲层的最高温度提高到1000 K以上,从而产生各种热效应。其物理过程涉及电场的畸变、等离子体的形成、电子的能量沉积和温度场的突变。
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来源期刊
CiteScore
1.60
自引率
0.00%
发文量
124
审稿时长
4.2 months
期刊介绍: COMPEL exists for the discussion and dissemination of computational and analytical methods in electrical and electronic engineering. The main emphasis of papers should be on methods and new techniques, or the application of existing techniques in a novel way. Whilst papers with immediate application to particular engineering problems are welcome, so too are papers that form a basis for further development in the area of study. A double-blind review process ensures the content''s validity and relevance.
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