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Simulation and experimentation of a single-phase claw-pole motor

Reinap, Avo LU ; Alaküla, Mats LU orcid ; Nord, G and Hultman, L (2006) In Compel 25(2). p.379-388
Abstract
Purpose - The purpose of the paper is to evaluate theoretically and experimentally the static and dynamic characteristics of a single-phase claw-pole motor using soft magnetic composite (SMC) for the stator core. Design/methodology/approach - On the basis of the static characteristics, which are measured and obtained from a series of 3D FE magnetostatic solutions, the dynamic characteristics are simulated according to a proposed control strategy. The same strategy is tested in dSpace control environment. Apart from the evaluation of the prototype SMC motor, some study has been made in order to improve the existing motor design. Findings - The static characteristics of the single-phase claw-pole motor have been modelled in 3D FE... (More)
Purpose - The purpose of the paper is to evaluate theoretically and experimentally the static and dynamic characteristics of a single-phase claw-pole motor using soft magnetic composite (SMC) for the stator core. Design/methodology/approach - On the basis of the static characteristics, which are measured and obtained from a series of 3D FE magnetostatic solutions, the dynamic characteristics are simulated according to a proposed control strategy. The same strategy is tested in dSpace control environment. Apart from the evaluation of the prototype SMC motor, some study has been made in order to improve the existing motor design. Findings - The static characteristics of the single-phase claw-pole motor have been modelled in 3D FE magnetostatic solver, where the rotor position and stator current have been changed. The characteristics compare well with the measurements, while the discrepancy with the cogging torque waveform needs further analyses and experiments to explain the real magnetization pattern of the plastic bounded ferrite magnet-ring and the influence of magnetic hysteresis. The 3D FE magnetostatic optimization routine shows the maximum quantities for magnetic coupling and static core loss. Furthermore it is used to obtain the improved pole distribution so that the resting position of the unexcited motor co-aligns at the position of the maximum electromagnetical torque. This is achieved by changing the angular width of claw-poles. The specific output of the maximum coupling torque from the single-phase claw-pole motor can be increased from the recent 0.1 to 0.6 Nm/kg at a temperature rise of 60 degrees. The simulations of dynamical characteristics show a good correlation with the experiments where the same control system in Simulink is applied to the prototype via dSpace. It is practically easier to implement a simple control strategy for the direct current controlled voltage source inverter. A more advantageous control system needs to be applied for the sampled current controller. Research limitations/implications - The influence of the magnetization of a multi-pole magnet ring is not considered while computing the static characteristics in 3D FE magnetostatic solver. Practical implications - The evaluation of the realistic magnetization pattern in the magnet aggravates the proper theoretical evaluation of static characteristics. Originality/value - The design of a small size powder core motor is faced with the complexity of evaluating properly the static characteristics, while the magnetization pattern is not exactly known. The broad search here is for an efficient tool to visualize the output of the 3D FE optimization for an improved design. (Less)
Please use this url to cite or link to this publication:
author
; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
magnetic variables control, electric motors, optimization techniques
in
Compel
volume
25
issue
2
pages
379 - 388
publisher
Emerald Group Publishing Limited
external identifiers
  • wos:000237037300011
  • scopus:33645526666
ISSN
0332-1649
DOI
10.1108/03321640610649050
language
English
LU publication?
yes
id
a75b912e-1717-4b88-ae7d-ba1b5f616952 (old id 410903)
date added to LUP
2016-04-01 16:43:34
date last changed
2022-10-06 01:24:41
@article{a75b912e-1717-4b88-ae7d-ba1b5f616952,
  abstract     = {{Purpose - The purpose of the paper is to evaluate theoretically and experimentally the static and dynamic characteristics of a single-phase claw-pole motor using soft magnetic composite (SMC) for the stator core. Design/methodology/approach - On the basis of the static characteristics, which are measured and obtained from a series of 3D FE magnetostatic solutions, the dynamic characteristics are simulated according to a proposed control strategy. The same strategy is tested in dSpace control environment. Apart from the evaluation of the prototype SMC motor, some study has been made in order to improve the existing motor design. Findings - The static characteristics of the single-phase claw-pole motor have been modelled in 3D FE magnetostatic solver, where the rotor position and stator current have been changed. The characteristics compare well with the measurements, while the discrepancy with the cogging torque waveform needs further analyses and experiments to explain the real magnetization pattern of the plastic bounded ferrite magnet-ring and the influence of magnetic hysteresis. The 3D FE magnetostatic optimization routine shows the maximum quantities for magnetic coupling and static core loss. Furthermore it is used to obtain the improved pole distribution so that the resting position of the unexcited motor co-aligns at the position of the maximum electromagnetical torque. This is achieved by changing the angular width of claw-poles. The specific output of the maximum coupling torque from the single-phase claw-pole motor can be increased from the recent 0.1 to 0.6 Nm/kg at a temperature rise of 60 degrees. The simulations of dynamical characteristics show a good correlation with the experiments where the same control system in Simulink is applied to the prototype via dSpace. It is practically easier to implement a simple control strategy for the direct current controlled voltage source inverter. A more advantageous control system needs to be applied for the sampled current controller. Research limitations/implications - The influence of the magnetization of a multi-pole magnet ring is not considered while computing the static characteristics in 3D FE magnetostatic solver. Practical implications - The evaluation of the realistic magnetization pattern in the magnet aggravates the proper theoretical evaluation of static characteristics. Originality/value - The design of a small size powder core motor is faced with the complexity of evaluating properly the static characteristics, while the magnetization pattern is not exactly known. The broad search here is for an efficient tool to visualize the output of the 3D FE optimization for an improved design.}},
  author       = {{Reinap, Avo and Alaküla, Mats and Nord, G and Hultman, L}},
  issn         = {{0332-1649}},
  keywords     = {{magnetic variables control; electric motors; optimization techniques}},
  language     = {{eng}},
  number       = {{2}},
  pages        = {{379--388}},
  publisher    = {{Emerald Group Publishing Limited}},
  series       = {{Compel}},
  title        = {{Simulation and experimentation of a single-phase claw-pole motor}},
  url          = {{http://dx.doi.org/10.1108/03321640610649050}},
  doi          = {{10.1108/03321640610649050}},
  volume       = {{25}},
  year         = {{2006}},
}