Three-Phase Bidirectional-Flyback Differential-Inverter for Synchronous Electrostatic Machines

2020 IEEE Energy Conversion Congress and Exposition (ECCE) Pub Date : 2020-10-11 DOI:10.1109/ECCE44975.2020.9236257

P. Killeen, D. Ludois

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引用次数: 1

Abstract

Synchronous electrostatic machines can deliver extremely low loss while holding rated torque, with recent direct drive demonstrations of 0.625 W/Nm holding torque. Until now, power electronics topologies have focused on the support of wide torque-speed operation of these machines, resulting in drive systems that are suboptimal for applications largely operating at stall. Leveraging the ability of these machines to support dc-voltages without saturation, bidirectional flyback DC-DC converters are arranged to form a compact three-phase differential-inverter from a line to line terminal perspective. The arrangement is analytically modelled and analyzed for the position and hold application. This topology provides large voltage-gain and reduced component count eliminating isolated gate drivers. Utilized in discontinuous conduction mode at high frequencies, the topology has reduced switching loss and reduced magnetic component sizes. These attributes provide a suitable roadmap for drive integration with the machine. For comparison to the analytical model the converter is simulated in PLECS and Vdq0 controller is utilized for charge-oriented control.

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同步静电电机用三相双向反激差分逆变器

同步静电电机在保持额定扭矩的同时可以提供极低的损耗，最近的直接驱动演示为0.625 W/Nm保持扭矩。到目前为止，电力电子拓扑主要集中在支持这些机器的大扭矩-速度运行上，导致驱动系统在大部分失速运行的应用中不是最佳的。利用这些机器支持无饱和直流电压的能力，双向反激DC-DC转换器从线路到线路终端的角度排列形成紧凑的三相差动逆变器。对该布置进行了分析建模，并对其位置和保持应用进行了分析。这种拓扑结构提供了大的电压增益和减少的元件数量，消除了隔离的栅极驱动器。在高频不连续导通模式下，该拓扑结构降低了开关损耗，减小了磁性元件的尺寸。这些属性为驱动器与机器的集成提供了合适的路线图。为了与解析模型进行比较，在PLECS中对变换器进行了仿真，并采用Vdq0控制器进行电荷定向控制。

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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2020 IEEE Energy Conversion Congress and Exposition (ECCE)

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