New Designs of a Two-Phase E-Core Switched Reluctance Machine by Optimizing the Magnetic Structure for a Specific Application: Concept, Design, and Analysis

Three new magnetic structures for an E-core SRM comprising two segmented stator cores or a monolithic stator core are proposed for good manufacturability, mechanically robustness, ease of assembly, and electromagnetic performance improvement. The E-core stator has four small poles with phase winding...

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Hauptverfasser:	Cheewoo Lee, Krishnan, R.
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Assembly Copper Design optimization Magnetic analysis Magnetic separation Magnetic switching Reluctance machines Rotors Stator cores Torque
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creator	Cheewoo Lee Krishnan, R.
description	Three new magnetic structures for an E-core SRM comprising two segmented stator cores or a monolithic stator core are proposed for good manufacturability, mechanically robustness, ease of assembly, and electromagnetic performance improvement. The E-core stator has four small poles with phase windings and two or four large poles (hereafter referred to as common poles), in between. The common poles do not have copper windings or permanent magnets. The common poles are shared by both phases for positive torque generation during the entire operation. The air gap around the common pole has constant and minimum reluctance irrespective of rotor position, by its unique design, and the two small stator poles experience variable reluctance with respect to rotor position. The segmented stator can be constructed with two independent and physically separate E-shaped cores with L-shaped or I-shaped yokes so that the straight back iron in the stator rather than curved back iron is suitable for assembly with other parts like end bells or brackets. The monolithic stator also has an L-shaped yoke for the same reason, and the new E-core SRMs are designed by means of pole arc optimization. The novel SRMs are compared to a conventional two-phase SRM. The comparison includes cost savings, torque, copper and core losses, efficiency, and radial force in order to validate the distinct features of the E-core SRMs. For experimental verification, laboratory testing of a segmented E-core SRM is conducted, and the simulated and measured phase currents and voltages correlate well.
doi_str_mv	10.1109/08IAS.2008.65
format	Conference Proceeding
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The E-core stator has four small poles with phase windings and two or four large poles (hereafter referred to as common poles), in between. The common poles do not have copper windings or permanent magnets. The common poles are shared by both phases for positive torque generation during the entire operation. The air gap around the common pole has constant and minimum reluctance irrespective of rotor position, by its unique design, and the two small stator poles experience variable reluctance with respect to rotor position. The segmented stator can be constructed with two independent and physically separate E-shaped cores with L-shaped or I-shaped yokes so that the straight back iron in the stator rather than curved back iron is suitable for assembly with other parts like end bells or brackets. The monolithic stator also has an L-shaped yoke for the same reason, and the new E-core SRMs are designed by means of pole arc optimization. The novel SRMs are compared to a conventional two-phase SRM. 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The E-core stator has four small poles with phase windings and two or four large poles (hereafter referred to as common poles), in between. The common poles do not have copper windings or permanent magnets. The common poles are shared by both phases for positive torque generation during the entire operation. The air gap around the common pole has constant and minimum reluctance irrespective of rotor position, by its unique design, and the two small stator poles experience variable reluctance with respect to rotor position. The segmented stator can be constructed with two independent and physically separate E-shaped cores with L-shaped or I-shaped yokes so that the straight back iron in the stator rather than curved back iron is suitable for assembly with other parts like end bells or brackets. The monolithic stator also has an L-shaped yoke for the same reason, and the new E-core SRMs are designed by means of pole arc optimization. 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The novel SRMs are compared to a conventional two-phase SRM. The comparison includes cost savings, torque, copper and core losses, efficiency, and radial force in order to validate the distinct features of the E-core SRMs. For experimental verification, laboratory testing of a segmented E-core SRM is conducted, and the simulated and measured phase currents and voltages correlate well.</abstract><pub>IEEE</pub><doi>10.1109/08IAS.2008.65</doi><tpages>8</tpages></addata></record>
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identifier	ISSN: 0197-2618
ispartof	2008 IEEE Industry Applications Society Annual Meeting, 2008, p.1-8
issn	0197-2618 2576-702X
language	eng
recordid	cdi_ieee_primary_4658853
source	IEEE Electronic Library (IEL) Conference Proceedings
subjects	Assembly Copper Design optimization Magnetic analysis Magnetic separation Magnetic switching Reluctance machines Rotors Stator cores Torque
title	New Designs of a Two-Phase E-Core Switched Reluctance Machine by Optimizing the Magnetic Structure for a Specific Application: Concept, Design, and Analysis
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