A Possible Method for Magnetostrictive Reduction of Vibration in Large Electrical Machines

This paper introduces a magnetic bimorph concept as a means of manipulating magnetostriction in the stator teeth so that components of magnetostrictive force act to cancel out selected components of Maxwell force. This leads to zero net electromagnetic excitation of targeted vibration modes and redu...

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Veröffentlicht in:	IEEE transactions on magnetics 2011-02, Vol.47 (2), p.374-385
Hauptverfasser:	Shahaj, Annabel, Garvey, Seamus D.
Format:	Artikel
Sprache:	eng
Schlagworte:	Cross-disciplinary physics: materials science rheology Design engineering Electrical machines Exact sciences and technology Excitation Finite element method Magnetic resonance Magnetism Magnetostriction Materials science Mathematical analysis noise Noise control Other topics in materials science Physics Saturation magnetization Stators Teeth Vibration vibration mitigation Vibration mode Vibrations
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container_title	IEEE transactions on magnetics
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creator	Shahaj, Annabel Garvey, Seamus D.
description	This paper introduces a magnetic bimorph concept as a means of manipulating magnetostriction in the stator teeth so that components of magnetostrictive force act to cancel out selected components of Maxwell force. This leads to zero net electromagnetic excitation of targeted vibration modes and reduces the vibration and resultant noise emission from the machine. The proposed noise reduction technique is suitable for large electrical machines with vibration modes that experience tooth rocking at natural frequencies within the range of acoustic interest. Experimental and finite-element investigations illustrate that this concept is a practical and low-cost method to implement without degrading the performance of the machine. A finite-element investigation has shown that the contributions to vibration of a large electrical machine from Maxwell forces in the air gap and the magnetostriction effect in the stator iron are comparable. Magnetostriction can act either to reduce or increase the overall modal excitation compared to the excitation of Maxwell forces.
doi_str_mv	10.1109/TMAG.2010.2095875
format	Article
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This leads to zero net electromagnetic excitation of targeted vibration modes and reduces the vibration and resultant noise emission from the machine. The proposed noise reduction technique is suitable for large electrical machines with vibration modes that experience tooth rocking at natural frequencies within the range of acoustic interest. Experimental and finite-element investigations illustrate that this concept is a practical and low-cost method to implement without degrading the performance of the machine. A finite-element investigation has shown that the contributions to vibration of a large electrical machine from Maxwell forces in the air gap and the magnetostriction effect in the stator iron are comparable. 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This leads to zero net electromagnetic excitation of targeted vibration modes and reduces the vibration and resultant noise emission from the machine. The proposed noise reduction technique is suitable for large electrical machines with vibration modes that experience tooth rocking at natural frequencies within the range of acoustic interest. Experimental and finite-element investigations illustrate that this concept is a practical and low-cost method to implement without degrading the performance of the machine. A finite-element investigation has shown that the contributions to vibration of a large electrical machine from Maxwell forces in the air gap and the magnetostriction effect in the stator iron are comparable. Magnetostriction can act either to reduce or increase the overall modal excitation compared to the excitation of Maxwell forces.</abstract><cop>New York, NY</cop><pub>IEEE</pub><doi>10.1109/TMAG.2010.2095875</doi><tpages>12</tpages></addata></record>
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subjects	Cross-disciplinary physics: materials science rheology Design engineering Electrical machines Exact sciences and technology Excitation Finite element method Magnetic resonance Magnetism Magnetostriction Materials science Mathematical analysis noise Noise control Other topics in materials science Physics Saturation magnetization Stators Teeth Vibration vibration mitigation Vibration mode Vibrations
title	A Possible Method for Magnetostrictive Reduction of Vibration in Large Electrical Machines
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