Reluctance motor and actuator design: finite-element model versus analytical model

Author

Perriard, Yves

Author_Institution

Integrated Actuator Lab., Swiss Fed. Inst. of Technol., Lausanne, Switzerland

Volume

40

Issue

4

fYear

2004

fDate

7/1/2004 12:00:00 AM

Firstpage

1905

Lastpage

1910

Abstract

Designing actuators or motors requires analysis of a lot of parameters such as length, temperature, efficiency, and weight. A global analysis to evaluate these parameters is possible. Three methods can be used: 1) an analytical method, allowing parametric study and parameter sensitivity analysis; 2) a finite-element model, which makes it possible to take into account nonlinearities, including the fringe effect; and 3) the analytical method, followed by a process of optimization, which makes it possible to reach an optimum based on an objective function and constraints. This paper describes each of these methodologies and compares them to help designers make a choice. Two examples to illustrate the three methods are a reluctance actuator and a brushless dc motor intended for a new intracardiac blood pump.

Keywords

actuators; brushless DC motors; finite element analysis; haemodynamics; optimisation; pumps; reluctance motors; actuators; analytical model; brushless dc motor; finite-element model; fringe effect; intracardiac blood pump; nonlinearities; optimization; parameter evaluation; parameter sensitivity analysis; parametric study; reluctance actuator; reluctance motor; thermal factors; Actuators; Analytical models; Brushless DC motors; Constraint optimization; DC motors; Finite element methods; Parametric study; Reluctance motors; Sensitivity analysis; Temperature sensors; Actuators; blood pumps; optimization methods; reluctance motors; thermal factors;

fLanguage

English

Journal_Title

Magnetics, IEEE Transactions on

Publisher

ieee

ISSN

0018-9464

Type

jour

DOI

10.1109/TMAG.2004.828932

Filename

1325360