Investigation of Resonance Avoidance Method for Vacuum Cleaner

Electromagnetic resonance in electric motors arises when the electromagnetic force frequency coincides with any of the motor's natural frequencies, causing excessive vibration and noise. To address this issue, it is crucial to design motors such that their natural frequencies do not closely ali...

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Veröffentlicht in:	IEEE open journal of industry applications 2023, Vol.4, p.328-335
Hauptverfasser:	Hwang, Woong, Kim, Jimin, Han, Jihoon, Kang, Wonsoo, Park, Sunghyuk
Format:	Artikel
Sprache:	eng
Schlagworte:	Design factors Electric motors Electromagnetic force Electromagnetic forces Electromagnetics Force Iron natural frequency noise Resonance Resonant frequencies Resonant frequency Shape stator core Stator cores Vacuum cleaners
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creator	Hwang, Woong Kim, Jimin Han, Jihoon Kang, Wonsoo Park, Sunghyuk
description	Electromagnetic resonance in electric motors arises when the electromagnetic force frequency coincides with any of the motor's natural frequencies, causing excessive vibration and noise. To address this issue, it is crucial to design motors such that their natural frequencies do not closely align with the electromagnetic force frequency. However, vacuum cleaner motors operate across a broad range of speeds, generating a multitude of electromagnetic force frequencies, which makes it challenging to establish natural frequencies that can avoid all possible electromagnetic resonances. This article presents a novel approach for shifting natural frequencies by adjusting the stiffness of stator cores. By integrating an auxiliary component with various design factors into the motor, a range of natural frequencies can be achieved. An optimal natural frequency that mitigates electromagnetic resonance was identified among these modified frequencies, and the subsequent enhancement in acoustic characteristics was demonstrated.
doi_str_mv	10.1109/OJIA.2023.3323343
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subjects	Design factors Electric motors Electromagnetic force Electromagnetic forces Electromagnetics Force Iron natural frequency noise Resonance Resonant frequencies Resonant frequency Shape stator core Stator cores Vacuum cleaners
title	Investigation of Resonance Avoidance Method for Vacuum Cleaner
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