An Equivalent Modeling Method for Electromagnetic Radiation of PWM Fans with Multiple Radiation Sources

An Equivalent Modeling Method for Electromagnetic Radiation of PWM Fans with Multiple Radiation Sources

Axial flow fans, used for heat dissipation in electronic equipment, may generate significant electromagnetic interference during PWM speed regulation. Due to its multiple radiation sources and relatively smaller size compared to the equipment, the radiation prediction model for equipment-level EMC a...

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Bibliographic Details
Main Authors: Jinsheng Yang, Xuan Zhao, Jingxuan Xia, Wei Zhang, Pingan Du, Baolin Nie
Format: Article
Language:English
Published: MDPI AG 2025-03-01
Series:Applied Sciences
Subjects:
axial flow fan
radiated interference
field source equivalence
Huygens principle
finite integration technique
Online Access:https://www.mdpi.com/2076-3417/15/6/2887
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Summary:Axial flow fans, used for heat dissipation in electronic equipment, may generate significant electromagnetic interference during PWM speed regulation. Due to its multiple radiation sources and relatively smaller size compared to the equipment, the radiation prediction model for equipment-level EMC analysis often involves a huge number of grids, which leads to computational difficulties and inefficiencies, and thus an equivalent modeling method for the electromagnetic radiation of PWM fan is presented. First, a detailed field-circuit coupling model of the radiation from winding and driving circuits is established using the time-domain finite-integral method with non-uniform grids. Then, a near-field hexahedron is defined to surround the fan, and the electromagnetic field of all its surfaces is derived based on the Huygens principle and calculated. Finally, the hexahedron encapsulating all radiation sources within the fan can be used in a higher level simulation as replicable and reusable equivalent sources. The proposed method is validated by a numerical example and actual measurements and applied to predict the radiation emissions within an electronic enclosure. The results show that the equivalent model can reduce 81.4% computation time and maintain good consistency in comparison to the detailed field-circuit coupling model.
ISSN:2076-3417

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