Short-Circuited Rotor Windings for Improving the Electromagnetic Saliency for Inductance- and Resistance-Based Self-Sensing Control | IEEE Conference Publication | IEEE Xplore
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Short-Circuited Rotor Windings for Improving the Electromagnetic Saliency for Inductance- and Resistance-Based Self-Sensing Control

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Christoph Hittinger; Ingo Hahn
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Abstract:

Self-sensing control of electrical machines has been a challenging topic in the field of control of electrical machines in the last years. This strategy can be used to om...Show More

Metadata

Abstract:

Self-sensing control of electrical machines has been a challenging topic in the field of control of electrical machines in the last years. This strategy can be used to omit the encoder, which has positive impact on the cost and the volume of the electrical machine. In this work, a concept for the improvement of the self-sensing capability of an electrical machine with surface mounted magnets by applying short-circuited windings on the rotor will be presented. These windings are supposed to increase the electromagnetic saliency that is required for an electrical machine to be suitable for self-sensing control. First, the manufacturing process will be described shortly. Second, the parameters that are necessary for self-sensing control will be presented for inductance- as well as resistance-based saliency tracking. The parameters were identified on a test bench. Finally, the influence of the concept on the total losses of the machine will be evaluated by measurement results.
Published in: 2019 IEEE 28th International Symposium on Industrial Electronics (ISIE)
Date of Conference: 12-14 June 2019
Date Added to IEEE Xplore: 01 August 2019
ISBN Information:

ISSN Information:

DOI: 10.1109/ISIE.2019.8781234
Conference Location: Vancouver, BC, Canada
References is not available for this document.
Contents

I. Introduction

The mechanical encoder that is in general mandatory for operating electrical machines includes some disadvantages such as the volume and the cost of the machine or the influence of the environment on it. If some requirements are fulfilled, this mechanical part of the machine can be obsolete when using self-sensing control. At higher speeds, techniques based on the back-EMF of the machine are applicable by only evaluating a certain voltage signal of the machine during operation. At declining speeds, however, the signal-to-noise ratio gets worse and the position estimation based on the back-EMF is no longer possible [1]. Hence, an additional test signal needs to be injected. For still being able to estimate the correct rotor position of the machine it requires an electromagnetic saliency, which needs to be present at every rotor position and operating point. The first one is e.g investigated in [2], the latter one in [3]. A general overview of typically used techniques for encoderless control in the present research is carried out in [4]. Cross-coupling effects between the high frequency (HF-) inductances and resistances are the crucial point of these concepts using test signal injection. When the saturation of the machine increases, these effects rise as well [5] and the electromagnetic saliency strongly decreases [2], [6]. For a vanishing saliency, the worst-case scenario is a total loss of the position information.

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