Thermal Analysis of Compulsator Based on Fluid-Structure Coupling and Distributed Convective Heat Transfer Coefficient

IF 1.3 4区 物理与天体物理 Q3 PHYSICS, FLUIDS & PLASMAS
Bofeng Zhu;Xiao Zhang;Tongyang Zhao;Tao Ma;Junyong Lu
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引用次数: 0

Abstract

Air-core compensated pulse alternator (compulsator) is an important technical approach to realize the miniaturization of pulse power supply (PPS) for electromagnetic launch (EML). When it discharges, the internal components especially windings are faced with extreme conditions of transient strong coupling of electromagnetic, force, and temperature fields, so efficient thermal management design is one of the key technologies for its safe and reliable operation. In this article, a new thermal analysis method based on fluid-structure coupling and distributed convective heat transfer coefficient is proposed. Compared with the traditional calculation method which uses constant convective heat transfer coefficient, it has higher accuracy and is conducive to more precise analysis of continuous discharge temperature distribution and active cooling effect under extreme conditions. Combined with a design example of the GW scale compulsator, the thermal analysis results of forced air cooling and active water cooling are compared and analyzed. The research conclusions have important reference significance for guiding the overall design of the compulsator, and the research methods can be extended to other electrical thermal analysis occasions.
基于流固耦合和分布式对流传热系数的压缩机热分析
空芯补偿脉冲交流发电机(强迫器)是实现电磁发射(EML)脉冲电源(PPS)小型化的重要技术手段。放电时,内部元件尤其是绕组面临电磁场、力场和温度场瞬时强耦合的极端条件,因此高效的热管理设计是其安全可靠运行的关键技术之一。本文提出了一种基于流固耦合和分布式对流传热系数的新型热分析方法。与使用恒定对流传热系数的传统计算方法相比,它具有更高的精度,有利于更精确地分析极端条件下的连续排放温度分布和主动冷却效果。结合 GW 级强制器的设计实例,对比分析了强制风冷和主动水冷的热分析结果。研究结论对指导逼变器的整体设计具有重要的参考意义,研究方法可推广到其他电热分析场合。
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
IEEE Transactions on Plasma Science
IEEE Transactions on Plasma Science 物理-物理:流体与等离子体
CiteScore
3.00
自引率
20.00%
发文量
538
审稿时长
3.8 months
期刊介绍: The scope covers all aspects of the theory and application of plasma science. It includes the following areas: magnetohydrodynamics; thermionics and plasma diodes; basic plasma phenomena; gaseous electronics; microwave/plasma interaction; electron, ion, and plasma sources; space plasmas; intense electron and ion beams; laser-plasma interactions; plasma diagnostics; plasma chemistry and processing; solid-state plasmas; plasma heating; plasma for controlled fusion research; high energy density plasmas; industrial/commercial applications of plasma physics; plasma waves and instabilities; and high power microwave and submillimeter wave generation.
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