Cogging Torque Reduction of Single-Phase Brushless DC Motor With a Tapered Air-Gap Using Optimizing Notch Size and Position

Author

Young-Un Park ; Ju-Hee Cho ; Dae-kyong Kim

Author_Institution

Sunchon Nat. Univ., Suncheon, South Korea

Volume

51

Issue

6

fYear

2015

Firstpage

4455

Lastpage

4463

Abstract

This paper reports a stator shape optimization design for reducing the cogging torque of single-phase brushless dc (BLDC) motors by adopting an asymmetric air-gap to make them self-starting. A time step 2-D finite-element analysis (FEA) was carried out to analyze the characteristics of the single-phase BLDC motor. The Kriging model combined with Latin hypercube sampling and a genetic algorithm were used to reduce the cogging torque and maintain the efficiency and torque. As an optimal design result, the cogging torque of the optimal model was reduced. Finally, the analysis and optimal design results were confirmed by FEA as well as by experimental results.

Keywords

brushless DC motors; finite element analysis; genetic algorithms; machine insulation; sampling methods; BLDC motors; FEA; Kriging model; Latin hypercube sampling; asymmetric air-gap; cogging torque reduction; genetic algorithm; optimizing notch size; single-phase brushless DC motor; stator shape optimization design; tapered air-gap; time step 2D finite-element analysis; Air gaps; Brushless DC motors; Forging; Mathematical model; Rotors; Stators; Torque; Cogging torque; notch; optimal design; single-phase Brushless DC motor; single-phase brushless dc (BLDC) motor; tapered air-gap;

fLanguage

English

Journal_Title

Industry Applications, IEEE Transactions on

Publisher

ieee

ISSN

0093-9994

Type

jour

DOI

10.1109/TIA.2015.2453131

Filename

7150545