Force prediction including hysteresis effects in a short-stroke reluctance actuator using a 3d-FEM and the preisach model

N.H. Vrijsen, J.W. Jansen, E. Lomonova

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/CongresprocedureConferentiebijdrageAcademicpeer review

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Uittreksel

Magnetic hysteresis effects, present in the force of an E-core reluctance actuator, are examined by simulations and measurements. Simulations have been performed with a 3d finite element method (3d-FEM) and a Preisach model, which is extended with a dynamic magnetic equivalent circuit (MEC) model. Both simulation methods are first examined on the prediction of the magnetic flux density in a closed- and open toroid for dc- and ac excitations. Finally, both methods are used to predict the force of the E-core reluctance actuator, which is compared to ac force measurements performed with a piezoelectric load cell.
Originele taal-2Engels
TitelProceedings of the Ninth International Symposium on Linear Drives for Industry Applications (LDIA13), 7-10 July 2013, Hangzhou, China
Pagina'sID362-1/6
StatusGepubliceerd - 2013

Vingerafdruk

reluctance
strokes
finite element method
actuators
hysteresis
predictions
magnetic circuits
toroids
simulation
equivalent circuits
magnetic flux
flux density
cells
excitation

Citeer dit

Vrijsen, N. H., Jansen, J. W., & Lomonova, E. (2013). Force prediction including hysteresis effects in a short-stroke reluctance actuator using a 3d-FEM and the preisach model. In Proceedings of the Ninth International Symposium on Linear Drives for Industry Applications (LDIA13), 7-10 July 2013, Hangzhou, China (blz. ID362-1/6)
Vrijsen, N.H. ; Jansen, J.W. ; Lomonova, E. / Force prediction including hysteresis effects in a short-stroke reluctance actuator using a 3d-FEM and the preisach model. Proceedings of the Ninth International Symposium on Linear Drives for Industry Applications (LDIA13), 7-10 July 2013, Hangzhou, China. 2013. blz. ID362-1/6
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title = "Force prediction including hysteresis effects in a short-stroke reluctance actuator using a 3d-FEM and the preisach model",
abstract = "Magnetic hysteresis effects, present in the force of an E-core reluctance actuator, are examined by simulations and measurements. Simulations have been performed with a 3d finite element method (3d-FEM) and a Preisach model, which is extended with a dynamic magnetic equivalent circuit (MEC) model. Both simulation methods are first examined on the prediction of the magnetic flux density in a closed- and open toroid for dc- and ac excitations. Finally, both methods are used to predict the force of the E-core reluctance actuator, which is compared to ac force measurements performed with a piezoelectric load cell.",
author = "N.H. Vrijsen and J.W. Jansen and E. Lomonova",
year = "2013",
language = "English",
pages = "ID362--1/6",
booktitle = "Proceedings of the Ninth International Symposium on Linear Drives for Industry Applications (LDIA13), 7-10 July 2013, Hangzhou, China",

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Vrijsen, NH, Jansen, JW & Lomonova, E 2013, Force prediction including hysteresis effects in a short-stroke reluctance actuator using a 3d-FEM and the preisach model. in Proceedings of the Ninth International Symposium on Linear Drives for Industry Applications (LDIA13), 7-10 July 2013, Hangzhou, China. blz. ID362-1/6.

Force prediction including hysteresis effects in a short-stroke reluctance actuator using a 3d-FEM and the preisach model. / Vrijsen, N.H.; Jansen, J.W.; Lomonova, E.

Proceedings of the Ninth International Symposium on Linear Drives for Industry Applications (LDIA13), 7-10 July 2013, Hangzhou, China. 2013. blz. ID362-1/6.

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/CongresprocedureConferentiebijdrageAcademicpeer review

TY - GEN

T1 - Force prediction including hysteresis effects in a short-stroke reluctance actuator using a 3d-FEM and the preisach model

AU - Vrijsen, N.H.

AU - Jansen, J.W.

AU - Lomonova, E.

PY - 2013

Y1 - 2013

N2 - Magnetic hysteresis effects, present in the force of an E-core reluctance actuator, are examined by simulations and measurements. Simulations have been performed with a 3d finite element method (3d-FEM) and a Preisach model, which is extended with a dynamic magnetic equivalent circuit (MEC) model. Both simulation methods are first examined on the prediction of the magnetic flux density in a closed- and open toroid for dc- and ac excitations. Finally, both methods are used to predict the force of the E-core reluctance actuator, which is compared to ac force measurements performed with a piezoelectric load cell.

AB - Magnetic hysteresis effects, present in the force of an E-core reluctance actuator, are examined by simulations and measurements. Simulations have been performed with a 3d finite element method (3d-FEM) and a Preisach model, which is extended with a dynamic magnetic equivalent circuit (MEC) model. Both simulation methods are first examined on the prediction of the magnetic flux density in a closed- and open toroid for dc- and ac excitations. Finally, both methods are used to predict the force of the E-core reluctance actuator, which is compared to ac force measurements performed with a piezoelectric load cell.

M3 - Conference contribution

SP - ID362-1/6

BT - Proceedings of the Ninth International Symposium on Linear Drives for Industry Applications (LDIA13), 7-10 July 2013, Hangzhou, China

ER -

Vrijsen NH, Jansen JW, Lomonova E. Force prediction including hysteresis effects in a short-stroke reluctance actuator using a 3d-FEM and the preisach model. In Proceedings of the Ninth International Symposium on Linear Drives for Industry Applications (LDIA13), 7-10 July 2013, Hangzhou, China. 2013. blz. ID362-1/6