EMS磁悬浮模型中与LSM推进系统接口的多个混合HTS电磁铁的电磁分析

Y. Chung, C. Lee, Mihye Jang
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引用次数: 2

摘要

本文介绍了基于电磁悬架(EMS)模型的时速400公里以上的磁悬浮车辆系统。这种磁悬浮系统由高温超导磁体、正常导电磁体和推进系统组成。混合电磁铁(EM)耗能小,能保持较大的悬架间隙。推进系统实现了车辆沿导轨推进和辅助制动的作用。特别是,由于基于ems的磁悬浮模型的本质是在高速运行时保持稳定的悬浮力,因此为了平衡悬浮间隙,需要对悬浮力和推进力进行分析。本文描述了基于电磁分析的悬浮力的理论性质,并构建了基于电磁悬浮(EMS)的磁悬浮车辆原型系统。根据仿真结果,得到了高速推进条件下变悬架间隙的设计参数。
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Electromagnetic analysis for multiple hybrid HTS electromagnets interfaced with LSM propulsion system in EMS maglev model
This study introduces over 400 km/h maglev vehicle system based on electromagnetic suspension (EMS) model. Such a maglev system is composed of high temperature superconducting (HTS) magnet, normal conducting magnet and propulsion system. The hybrid electromagnet (EM) consumes little power to keep large suspension gap. The propulsion system realizes to propel the vehicle along the guide-way and assist in braking action. Especially, as the essential point of EMS-based maglev model is to keep the stable suspension force in the high speed operation, the levitation and propulsion forces should be analyzed in order to equilibrate the suspension gap. In this paper, theoretical properties of the levitation force based on electromagnetic analysis are described, as we have been constructed a proto-type electromagnetic suspension (EMS) based maglev vehicle system. Based on the simulation results, we obtained the design parameters for variation suspension gap under high speed propulsion condition.
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