Magnetic Simulation and Analysis of Radial Flux Permanent Magnet Generator using Finite Element Method

Abstract

This paper discusses magnetic simulation and analysis of radial flux permanent magnet generator (PMG) using finite element method (FEM) by utilizing open source software FEMM 4.2. The specification of generator is 25 V, 28 A, 3 phase, 300 rpm. The analyzed magnetic flux was in the air gap, stator teeth and slots to find out the distribusian pattern and its fluctuation. The simulations were conducted in no-load and nominal load (28 A) conditions. Furthermore, the maximum flux density of simulation (B g(sim) ) was used to calculate phase voltage E ph to find out the magnitude of generated electromotive force (EMF). The calculation results were presented as voltage vs. rotation graph in no-load condition and voltage vs. current graph in nominal load condition. Both graphs were validated using E ph from experiment result (E ph(exp) ) and E ph whose B g value was obtained from analytical calculation (E ph(calc) ). The final results showed that in no-load condition, E ph graph with B g(sim) (E ph(sim) ) was close to E ph(exp) and E ph(calc). The error rate with respect to the experiment was 6,9%. In nominal load condition, E ph(sim) graph almost coincided with E ph(calc.) graph, with the voltage drop of both was 0,441 V. Both graphs however were far different from E ph(exp) graph, which had 9 V of voltage drop. The overall results demonstrated that magnetic distribution pattern presented by FEM was very helpful to avoid magnetic flux accumulation in a particular segment. Besides, B g(sim) made the process to predict the value of E ph became easier.