
Contol of Surface Mounted Permanent Magnet Motors with Special Application to Motors with Fractional-Slot Concentrated Windings
Author(s) -
N.A. Patil,
J.S. Lawler,
J.W. McKeever
Publication year - 2007
Language(s) - English
Resource type - Reports
DOI - 10.2172/921784
Subject(s) - oak ridge national laboratory , electromagnetic coil , controller (irrigation) , inductance , control theory (sociology) , voltage , inverter , engineering , magnet , steady state (chemistry) , synchronous motor , counter electromotive force , computer science , electrical engineering , control (management) , physics , agronomy , chemistry , artificial intelligence , nuclear physics , biology
A 30-pole, 6-kW prototype of a fractional-slot permanent magnet synchronous motor (PMSM) design has been developed to operate at a maximum speed of 6000 rpm [1,2]. This machine has significantly more inductance than regular PMSMs with distributed windings. The prototype was delivered in April 2006 to the Oak Ridge National Laboratory (ORNL) for testing and development of a suitable controller. To prepare for this test/control development effort, ORNL used PMSM models developed over a number of previous studies to preview the control issues that arise when a dynamic controller drives a high inductance PMSM machine during steady state performance evaluations. The detailed steady state model developed includes all motor and inverter loss mechanisms and was useful for assessing the performance of the dynamic controller before it was put into operation. This report documents the results of tests demonstrating the effectiveness of ORNL's simple low-cost control scheme during characterization of the fractional-slot concentrated windings (FSCW) PMSM motor. The control scheme is simple because only the supply voltage magnitude and the phase angle between the back-electromotive force (emf) and the supply voltage is controlled. It is low-cost because it requires no current or phase voltage sensors