An effective start-up algorithm for sensorless synchronous reluctance and IPM motor drives

2017 IEEE 12th International Conference on Power Electronics and Drive Systems (PEDS) Pub Date : 2017-12-01 DOI:10.1109/PEDS.2017.8289167

L. Ortombina, F. Tinazzi, M. Zigliotto

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引用次数: 4

Abstract

In the last decade, interior permanent magnet and synchronous reluctance motors are receiving attention from both academic and industrial environments, that appreciate the considerable advantages in terms of cost reduction and power density. However, these motors call for more advanced control techniques, due to the rotor anisotropy and the nonlinearity of the magnetic circuit. Reliability and cost also push towards sensorless solutions. Often, the fundamental-frequency based techniques are preferred to the high frequency injection, for the noise and vibrations that the latter implies. Unfortunately, the former cannot work down to zero speed. The aim of this paper is the study and development of a simple and effective start-up technique for sensorless synchronous motor drives. Merged with fundamental-frequency based sensorless control, it yields a full-range ac drive that fits for many applications that do not require steady state operation at low/null speed. In particular, the paper paves the way for integrating the motor model in the start-up design, highlighting pitfalls of the standard methods and showing how to improve the transition to the closed-loop control.

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无传感器同步磁阻和IPM电机驱动的有效启动算法

在过去的十年中，内部永磁和同步磁阻电机受到学术界和工业界的关注，它们在降低成本和功率密度方面具有相当大的优势。然而，由于转子的各向异性和磁路的非线性，这些电机需要更先进的控制技术。可靠性和成本也推动了无传感器解决方案的发展。通常，基于基频的技术比高频注入更受欢迎，因为后者意味着噪音和振动。不幸的是，前者不能工作到零速度。本文的目的是研究和开发一种简单有效的无传感器同步电机驱动启动技术。与基于基频的无传感器控制相结合，它产生了一个全范围的交流驱动器，适用于许多不需要在低/零速度下稳定运行的应用。特别是，本文为将电机模型集成到启动设计中铺平了道路，突出了标准方法的缺陷，并展示了如何改善向闭环控制的过渡。

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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2017 IEEE 12th International Conference on Power Electronics and Drive Systems (PEDS)

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