Abstract
This paper presents a comparison between two design methodologies applied to permanent magnet synchronous machines for hybrid and electric vehicles (HEVs and EVs). Both methodologies are based on 2D finite element models and coupled to a genetic algorithm to optimize complex non-linear geometries such as multi-layer permanent magnet machines. To reduce the computation duration to evaluate Induced Voltage and Iron Losses for a given electrical machine configuration, a new methodology based on geometrical symmetries and magnetic symmetries are used and is detailed. Two electromagnetic models have been developed and used in the design stage. The first model was the stepped rotor position finite element analysis called abc model which considered the spatial harmonics without any approximation of the waveform of flux linkage inside the stator, and the second model was based on a fixed rotor position called dq model, with the approximation that the waveform of flux linkage inside the stator was sinuous. These two methodologies are applied to the design of a synchronous machine for HEVs and EVs applications. Design results and performances are analyzed, and the advantages and drawbacks of each methodology are presented. It was found that the dq model is at least 5 times faster than the abc model with high precision for both the torque and induce voltage evaluation in most cases. However, it is not the case for the iron losses computation. The iron loss model based on dq model is less accurate than the abc model with a relative deviation from the abc model greater than 70% at high control angle. The choice of the electromagnetic model during the optimization process will therefore influence the geometry and the performances of the obtained electrical machine after the optimization.
Highlights
Electric vehicles (EVs) appear today as one of the solutions supported by the policies of many countries to reduce pollution and achieve global climate change objectives.The electric vehicle is suitable for urban use
To overcome the computation time issue, we developed two electromagnetic models and computed magnetostatics finite elements approach (FEA) on XFEMM®, which is an “open source code” directly integrated into MATLAB® and allows a fast evaluation of finite element (FE) calculations [13]
To see the influence that the choice of electromagnetic model could have on the sizing of an electrical machine, we optimized a synchronous magnet machine using the two developed electromagnetic models (“abc model” and “dq model”)
Summary
The electric vehicle is suitable for urban use. The main obstacles to its deployment are the cost of the vehicle and access to charging. Reducing the cost of electric vehicles involves reducing the cost of powertrain components. The main components of an electric vehicle’s powertrain are the battery, the power converter, and the electric motor. The battery is one of the most important parts of the conversion chain due to its limited on-board energy and high cost (around 30% of the vehicle price). To efficiently use this on-board energy, we would need to optimize the energy efficiency of the other powertrain components. We are interested in the optimal design of the electrical machine
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