Frontiers | Effective ignition energy for capacitor short-circuit discharge in explosive environments

IF 1.9 3区 物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY
Wang Dangshu, Yang Likang, Shulin Liu, Xinxia Wang, Song Luwen, Wu Fengjuan
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Abstract

Capacitors short-circuit discharge in an explosive environment can ignite and detonate the surrounding explosive media, causing dangerous accidents. At low voltages, this kind of discharge constitutes a micro-nano discharge; because the discharge gaps here are of the order of only microns to nanometers, the discharge process, electrode energy consumption, explosive media ignition energy, and other energy relationships are unclear. To study the relationships between the capacitor storage energy and various kinds of dissipation energies under short-circuit discharge, a model comprising conical and spherical cylinder microbumps is proposed based on the cathode surface morphology obtained by three-dimensional profiling and scanning electron microscopy, respectively. Then, the second-order non-chi-squared differential equations were established based on the principle of energy conservation and heat balance to deduce the relationships between the cathode surface temperature and height of the microbump, conical angle, and spherical radius; further, the energy consumed by the anode surface is calculated based on the theory of heat transfer. Using heat conduction theory, the energy consumed by the microbumps on the cathode surface is calculated, and the energy consumed on the anode surface is deduced using the surface heat source as the loading heat source. The residual energy of the capacitor is calculated from the discharge time and voltages before and after discharge, and the effective energy of the gas is calculated using the law of conservation of energy. Finally, the discharge channel energy, electrode energy consumption, and end residual energy of the discharge capacitor are used to derive the effective ignition energy of the explosive gas. This research is of great significance for the design of intrinsically safe circuits with high power.
Frontiers | 爆炸环境中电容器短路放电的有效点火能量
电容器在爆炸环境中短路放电会点燃和引爆周围的爆炸介质,造成危险事故。在低电压下,这种放电构成微纳米放电;由于这里的放电间隙仅为微米到纳米数量级,放电过程、电极能耗、爆炸介质点燃能等能量关系尚不清楚。为了研究短路放电下电容器储能与各种耗散能量之间的关系,根据三维轮廓分析和扫描电子显微镜分别获得的阴极表面形貌,提出了由锥形和球形圆柱体微凸块组成的模型。然后,根据能量守恒和热平衡原理建立了二阶非智平方微分方程,推导出阴极表面温度与微凸块高度、圆锥角和球面半径之间的关系;再根据传热理论计算出阳极表面消耗的能量。利用热传导理论计算阴极表面微凸块消耗的能量,并以表面热源作为负载热源推算阳极表面消耗的能量。根据放电时间和放电前后的电压计算出电容器的剩余能量,并利用能量守恒定律计算出气体的有效能量。最后,利用放电通道能量、电极能量消耗和放电电容器的末端残余能量得出爆炸气体的有效点火能量。这项研究对大功率本质安全电路的设计具有重要意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Frontiers in Physics
Frontiers in Physics Mathematics-Mathematical Physics
CiteScore
4.50
自引率
6.50%
发文量
1215
审稿时长
12 weeks
期刊介绍: Frontiers in Physics publishes rigorously peer-reviewed research across the entire field, from experimental, to computational and theoretical physics. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, engineers and the public worldwide.
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