Title :
Magnetic induction micromachine-part III:Eddy currents and nonlinear effects
Author :
Koser, Hur ; Lang, Jeffrey H.
Author_Institution :
Electr. Eng. Dept., Yale Univ., New Haven, CT, USA
fDate :
4/1/2006 12:00:00 AM
Abstract :
The magnetic induction micromachine fabricated in Part II was not laminated, as designed in Part I. Consequently, eddy currents in the stator core, and the associated nonlinear saturation, significantly decreased its performance from that predicted in Part I. To investigate and explain these phenomena and their consequences, this paper models the behavior of the solid-stator-core machine fabricated in Part II using a finite-difference time-domain numerical analysis. The inherent stiffness in the time-domain integration of Maxwell´s equations is mitigated via reducing the speed of light artificially by five orders of magnitude, while taking special care that assumptions of magneto-quasi-static behavior are still met. The results from this model are in very good agreement with experimental data from the tethered magnetic induction micro motor.
Keywords :
Maxwell equations; eddy currents; finite difference time-domain analysis; induction motors; micromotors; stators; Maxwell equations; eddy currents; finite-difference time-domain numerical analysis; magnetic induction micromachine; magneto-quasistatic behavior; nonlinear effects; nonlinear saturation; solid-stator-core machine; tethered magnetic induction micromotor; Eddy currents; Finite difference methods; Maxwell equations; Micromotors; Numerical analysis; Predictive models; Saturation magnetization; Solid modeling; Stator cores; Time domain analysis; Eddy currents; finite-difference time-domain (FDTD); magnetic induction; micromotor; saturation;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2006.872240
