Optimal Torque Angle for a Switched Brushless Doubly Fed Reluctance Machine

A brushless doubly fed reluctance machine (BDFRM) offers several advantages over a single-port machine since it requires a partially rated power converter, provides reduced maintenance, and operates without permanent magnets. A conventional design approach for BDFRMs considers equal electrical loadi...

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Veröffentlicht in:	IEEE transactions on industrial electronics (1982) 2024-08, p.1-11
Hauptverfasser:	Agrawal, Shivang, Chouhdry, Hadi, Mukherjee, Debranjan, Banerjee, Arijit
Format:	Artikel
Sprache:	eng
Schlagworte:	Brushless converter voltage doubly fed Loading modelling Optimization Rotors space phasors Stator windings Switches Torque torque angle torque ripple Voltage
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creator	Agrawal, Shivang Chouhdry, Hadi Mukherjee, Debranjan Banerjee, Arijit
description	A brushless doubly fed reluctance machine (BDFRM) offers several advantages over a single-port machine since it requires a partially rated power converter, provides reduced maintenance, and operates without permanent magnets. A conventional design approach for BDFRMs considers equal electrical loadings on both of its windings and a torque angle of 90o, which are an extension of typical constraints for uniform air-gap sinusoidal machines. However, these constraints in BDFRM sacrifice torque density. Accounting for effect of the rotor flux-barriers on the mean and ripple torque, the optimization framework proposes a candidate design having unequal electrical loadings and a torque angle of 117o to maximize torque density. It is shown that the optimal design is capable of producing 84% more torque as compared to the conventional design approach. This article, first, shows that a torque angle of greater than 90o is required to maximize the torque-producing component of secondary stator current using space phasors. Next, a switched-drive architecture is described that reconfigures one of the stator excitations on the fly to enable a wide-speed range operation. Online reconfiguration extends the use of BDFRM to many wide-speed range applications, such as propulsion systems, while preserving the benefit of fractionally rated power electronics. Using the switched-drive architecture can reduce the converter voltage rating by 47% as compared to the conventional-drive for the prototype BDFRM. The experimental results are provided to validate the proposed analytical approach.
doi_str_mv	10.1109/TIE.2024.3423438
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A conventional design approach for BDFRMs considers equal electrical loadings on both of its windings and a torque angle of 90o, which are an extension of typical constraints for uniform air-gap sinusoidal machines. However, these constraints in BDFRM sacrifice torque density. Accounting for effect of the rotor flux-barriers on the mean and ripple torque, the optimization framework proposes a candidate design having unequal electrical loadings and a torque angle of 117o to maximize torque density. It is shown that the optimal design is capable of producing 84% more torque as compared to the conventional design approach. This article, first, shows that a torque angle of greater than 90o is required to maximize the torque-producing component of secondary stator current using space phasors. Next, a switched-drive architecture is described that reconfigures one of the stator excitations on the fly to enable a wide-speed range operation. Online reconfiguration extends the use of BDFRM to many wide-speed range applications, such as propulsion systems, while preserving the benefit of fractionally rated power electronics. Using the switched-drive architecture can reduce the converter voltage rating by 47% as compared to the conventional-drive for the prototype BDFRM. 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Online reconfiguration extends the use of BDFRM to many wide-speed range applications, such as propulsion systems, while preserving the benefit of fractionally rated power electronics. Using the switched-drive architecture can reduce the converter voltage rating by 47% as compared to the conventional-drive for the prototype BDFRM. 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A conventional design approach for BDFRMs considers equal electrical loadings on both of its windings and a torque angle of 90o, which are an extension of typical constraints for uniform air-gap sinusoidal machines. However, these constraints in BDFRM sacrifice torque density. Accounting for effect of the rotor flux-barriers on the mean and ripple torque, the optimization framework proposes a candidate design having unequal electrical loadings and a torque angle of 117o to maximize torque density. It is shown that the optimal design is capable of producing 84% more torque as compared to the conventional design approach. This article, first, shows that a torque angle of greater than 90o is required to maximize the torque-producing component of secondary stator current using space phasors. Next, a switched-drive architecture is described that reconfigures one of the stator excitations on the fly to enable a wide-speed range operation. Online reconfiguration extends the use of BDFRM to many wide-speed range applications, such as propulsion systems, while preserving the benefit of fractionally rated power electronics. Using the switched-drive architecture can reduce the converter voltage rating by 47% as compared to the conventional-drive for the prototype BDFRM. The experimental results are provided to validate the proposed analytical approach.</abstract><pub>IEEE</pub><doi>10.1109/TIE.2024.3423438</doi><tpages>11</tpages><orcidid>https://orcid.org/0000-0001-9568-2371</orcidid><orcidid>https://orcid.org/0000-0002-6326-4981</orcidid><orcidid>https://orcid.org/0000-0003-3869-3159</orcidid></addata></record>
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subjects	Brushless converter voltage doubly fed Loading modelling Optimization Rotors space phasors Stator windings Switches Torque torque angle torque ripple Voltage
title	Optimal Torque Angle for a Switched Brushless Doubly Fed Reluctance Machine
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