Design of a compact winding for an axial-flux permanent-magnet brushless DC motor used in an electric two-wheeler

This paper describes the design of a compact winding for an axial-flux permanent-magnet brushless dc motor used in an electric two-wheeler. Once the motor design is carried out using the conventional method and the dimensions of the motor, magnet, etc. are determined, the electric loading and the ma...

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Published in:IEEE transactions on magnetics 2004-07, Vol.40 (4), p.2026-2028
Main Authors: Upadhyay, P.R., Rajagopal, K.R., Singh, B.P.
Format: Article
Language:English
Subjects:
Batteries
Brushless DC motors
Coils
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Conductors
DC motors
Design engineering
Exact sciences and technology
Magnetic properties and materials
Magnetism
Motors
Parametric study
Permanent magnet motors
Physics
Torque
Voltage
Wire
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cited_by cdi_FETCH-LOGICAL-c380t-6d6e610cf3d71f6a565b33ad381ddc6f4af2c62544f21892e1e48770174dff893
cites cdi_FETCH-LOGICAL-c380t-6d6e610cf3d71f6a565b33ad381ddc6f4af2c62544f21892e1e48770174dff893
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container_title IEEE transactions on magnetics
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creator Upadhyay, P.R.
Rajagopal, K.R.
Singh, B.P.
description This paper describes the design of a compact winding for an axial-flux permanent-magnet brushless dc motor used in an electric two-wheeler. Once the motor design is carried out using the conventional method and the dimensions of the motor, magnet, etc. are determined, the electric loading and the magnetomotive force (MMF) required to obtain the peak torque can be calculated. From the knowledge of the MMF requirement, a compact and efficient winding configuration has been achieved using a parametric study. The factors considered for the winding design are: 1) operating voltage; 2) number of poles; 3) cross-sectional area available for the winding; 4) conductor size; 5) number of parallel paths; 6) length of mean turn; 7) and the peak torque for a given value of AT/pole/phase. The motor voltage is decided based on the speed of the motor and aspects of the battery and the controller. The selected winding configuration for an 80-Nm peak torque, 48-V, three-phase motor is having 48 coils with each coil of 18 turns made out of 15 standard wire gauge copper wire. The resistance per phase is calculated as 0.0203 /spl Omega/.
doi_str_mv 10.1109/TMAG.2004.829820
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Once the motor design is carried out using the conventional method and the dimensions of the motor, magnet, etc. are determined, the electric loading and the magnetomotive force (MMF) required to obtain the peak torque can be calculated. From the knowledge of the MMF requirement, a compact and efficient winding configuration has been achieved using a parametric study. The factors considered for the winding design are: 1) operating voltage; 2) number of poles; 3) cross-sectional area available for the winding; 4) conductor size; 5) number of parallel paths; 6) length of mean turn; 7) and the peak torque for a given value of AT/pole/phase. The motor voltage is decided based on the speed of the motor and aspects of the battery and the controller. The selected winding configuration for an 80-Nm peak torque, 48-V, three-phase motor is having 48 coils with each coil of 18 turns made out of 15 standard wire gauge copper wire. 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Once the motor design is carried out using the conventional method and the dimensions of the motor, magnet, etc. are determined, the electric loading and the magnetomotive force (MMF) required to obtain the peak torque can be calculated. From the knowledge of the MMF requirement, a compact and efficient winding configuration has been achieved using a parametric study. The factors considered for the winding design are: 1) operating voltage; 2) number of poles; 3) cross-sectional area available for the winding; 4) conductor size; 5) number of parallel paths; 6) length of mean turn; 7) and the peak torque for a given value of AT/pole/phase. The motor voltage is decided based on the speed of the motor and aspects of the battery and the controller. The selected winding configuration for an 80-Nm peak torque, 48-V, three-phase motor is having 48 coils with each coil of 18 turns made out of 15 standard wire gauge copper wire. 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1941-0069
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source IEEE Electronic Library (IEL) Journals
subjects Batteries
Brushless DC motors
Coils
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Conductors
DC motors
Design engineering
Exact sciences and technology
Magnetic properties and materials
Magnetism
Motors
Parametric study
Permanent magnet motors
Physics
Torque
Voltage
Wire
title Design of a compact winding for an axial-flux permanent-magnet brushless DC motor used in an electric two-wheeler
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