Sensorless field oriented control of multiple-motors fed by multiple-converters systems

2017 IEEE International Symposium on Sensorless Control for Electrical Drives (SLED) Pub Date : 2017-09-01 DOI:10.1109/SLED.2017.8078456

S. Foti, A. Testa, S. de Caro, T. Scimone, M. Pulvirenti

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引用次数: 5

Abstract

On Multiple-Motor systems fed by Multiple-Converter systems a set of electric motor drives share the load through a common mechanical coupling. Such a coupling is exploited in this paper to realize a sensorless field oriented control, based on a quite common back-emf technique to estimate the rotor flux angular position and an original approach to correct the estimation errors. The technique is based on the injection of very low frequency, sinusoidal signals on the current references of one of the motor drives. If the estimated rotor flux position is correct, the drive output torque does not show variations. Differently, if the estimation is incorrect, a torque ripple is generated at the frequency of the injected signal, whose effects on the system speed are easily compensated by the main speed controller. However, due to the mechanical coupling, an additional component of the reference torque current at the frequency of the injected signals is generated on all the other drives. By minimizing this component, the rotor flux position estimation can be effectively corrected, as well as errors in estimating the stator and rotor resistances.

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多变换器多电机无传感器磁场定向控制

在由多变频器系统驱动的多电机系统中，一组电动机驱动器通过一个共同的机械联轴器分担负载。本文利用这种耦合来实现无传感器的磁场定向控制，基于一种非常常见的反电动势技术来估计转子磁链角位置和一种原始的方法来修正估计误差。该技术基于在其中一个电机驱动器的电流参考上注入极低频正弦信号。如果估计的转子磁链位置是正确的，则驱动输出转矩不显示变化。不同的是，如果估计不正确，则在注入信号的频率处产生转矩脉动，其对系统速度的影响很容易由主速度控制器补偿。然而，由于机械耦合，在注入信号的频率上，在所有其他驱动器上产生了额外的参考转矩电流分量。通过最小化该分量，可以有效地修正转子磁链位置估计，以及定子和转子电阻估计的误差。

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 International Symposium on Sensorless Control for Electrical Drives (SLED)

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