Abstract: The problem in improving the high positioning precision of permanent
magnet linear synchronous motor (PMLSM) for direct drive conveyer is the large
detent force, which contains two components: one is the cogging force caused by
the interaction between the permanent magnet (PM) and the iron core, the other
is the end effect caused by the finite mover length. In this paper a force
compensator in the field oriented control (FOC) algorithm is employed to reduce
this detent force, thus the thrust and the normal force characteristics
analyses of PMLSM are of the most importance. First the characteristics of the
thrust and the normal force are simulated by finite element method (FEM), and
the relation of the thrust and the normal force to the q-axis current is
analyzed. Then the components of detent force are defined by Fourier series
using the curve fitting method, and compensated by injecting the instantaneous
currents using the FOC method. Finally the dynamic characteristics of this
PMLSM for direct drive conveyer are investigated, and the numerical results are
reported to validate the effectiveness of this proposed method.
Keywords: Permanent magnet linear synchronous motor, detect force, field oriented control, thrust ripple, current compensation
