Charge transfer evaluation in solid insulating materials encapsulating the gaseous voids of submillimeter dimensions using transmission line method

IF 1.2 4区 计算机科学 Q4 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Amin Shamsi, A. Ganjovi, Amirabbas Shayegani Akmal
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Abstract

: In this work, using a lumped RC circuit model which is based on transmission line modeling (TLM) method, the charge transfer in a solid insulating system encapsulating a gaseous void of submillimeter dimensions is evaluated. Here, both the dielectric material and gaseous void are considered simultaneously as a transmission line. The transmission line includes the capacitive and resistance elements and, the obtained circuit equations were coupled with the continuity and kinetic energy equations for charged species along with Poisson’s equation. These equations are solved via 4th order Runge-Kutta method and, the electric field and potential, density of all the charged species, discharge current and electron temperature are calculated in the gaseous media. Hence, the discharge propagation in the gaseous void and its mutual influences on dielectric medium are described. The partially penetration of electrons in the avalanche head into the anode dielectric bulk is shown, and it is observed that their movements towards the electrodes are much faster than ions. Besides, the total transferred charge particles at both the avalanche and streamer phases in the void is calculated. Besides, it was found that, the electrons temperature distribution completely influenced by electric field in the gaseous void. In addition, the effects of voids thickness and their location on the discharge current are examined. It is shown that, at the higher void thicknesses and for the cavities locating in the electrodes adjacent, the magnitude of discharge current increases
利用传输线法评估封装亚毫米级气态空隙的固体绝缘材料中的电荷转移情况
:在这项研究中,利用基于传输线建模(TLM)方法的整块 RC 电路模型,对封装亚毫米尺寸气态空隙的固体绝缘系统中的电荷传输进行了评估。在这里,介电材料和气态空隙同时被视为传输线。传输线包括电容和电阻元件,得到的电路方程与带电体的连续性和动能方程以及泊松方程相耦合。这些方程通过四阶 Runge-Kutta 方法求解,并计算出气体介质中的电场和电势、所有带电物质的密度、放电电流和电子温度。因此,放电在气体空隙中的传播及其对介质的相互影响得到了描述。研究显示了电子在雪崩头中向阳极电介质体的部分穿透,并观察到电子向电极的运动比离子快得多。此外,还计算了空隙中雪崩阶段和流线阶段转移的总电荷粒子。此外,还发现电子的温度分布完全受气态空隙中电场的影响。此外,还研究了空隙厚度及其位置对放电电流的影响。结果表明,当空隙厚度越大、空隙位置越靠近电极时,放电电流的大小会增加
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来源期刊
Turkish Journal of Electrical Engineering and Computer Sciences
Turkish Journal of Electrical Engineering and Computer Sciences COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-ENGINEERING, ELECTRICAL & ELECTRONIC
CiteScore
2.90
自引率
9.10%
发文量
95
审稿时长
6.9 months
期刊介绍: The Turkish Journal of Electrical Engineering & Computer Sciences is published electronically 6 times a year by the Scientific and Technological Research Council of Turkey (TÜBİTAK) Accepts English-language manuscripts in the areas of power and energy, environmental sustainability and energy efficiency, electronics, industry applications, control systems, information and systems, applied electromagnetics, communications, signal and image processing, tomographic image reconstruction, face recognition, biometrics, speech processing, video processing and analysis, object recognition, classification, feature extraction, parallel and distributed computing, cognitive systems, interaction, robotics, digital libraries and content, personalized healthcare, ICT for mobility, sensors, and artificial intelligence. Contribution is open to researchers of all nationalities.
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