Effects of Stator Iron Loss and Current-Loop Delay on Copper-Loss-Minimizing Torque Control of BLDCM: Analysis and Improvements

Copper-loss-minimizing torque control (CLMTC) method has been widely studied to reduce electromagnetic torque ripple and minimize copper loss of a brushless dc motor (BLDCM), but still suffers challenges to improve its performance. This paper presents a quantitative analysis of stator iron loss and...

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Bibliographic Details
Published inIEEE transactions on power electronics Vol. 34; no. 6; pp. 5620 - 5631
Main Authors Zhang, Haitao, Dou, Manfeng, Yan, Liming
Format Journal Article
LanguageEnglish
Published New York IEEE 01.06.2019
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Back electromotive force
Brushless dc motor (BLDCM)
Brushless motors
Copper
Copper loss
copper loss minimization
Core loss
current-loop delay
D C motors
Delay
Electromagnetics
Electromotive forces
Error analysis
Iron
Mathematical model
Product design
Quantitative analysis
Rotors
stator iron loss
Stators
Torque
torque control
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Summary:Copper-loss-minimizing torque control (CLMTC) method has been widely studied to reduce electromagnetic torque ripple and minimize copper loss of a brushless dc motor (BLDCM), but still suffers challenges to improve its performance. This paper presents a quantitative analysis of stator iron loss and current-loop delay effects on CLMTC. In the analysis, the iron-loss-included torque equation that only suits for sinusoidal back electromotive force (EMF) is modified to cover the case of nonsinusoidal back EMF. It is concluded that the iron loss effect brings about significant torque generation error and the delay effect leads to torque ripple that increases linearly with the delay angle. Two improvements are proposed, one of which redefines the condition of an optimal motor current vector to compensate for the iron loss effect. The other one aims to suppress the delay effect by preshaping current reference based on delay characteristic of the loop. The improvements can be performed effectively on a microprocessor to realize a better CLMTC method with reduced torque generation error and torque ripple. Both the analysis and improvements are experimentally validated on a 0.95 kW BLDCM setup.
ISSN:0885-8993
1941-0107
DOI:10.1109/TPEL.2018.2867557