A key to the cost effective mass manufacturing is unification of the components among the whole performance range of vehicles – from light vehicles, through C and D class passenger cars, to performance cars and light duty vehicles and buses. This part of the work was concentrated on requirement analysis and developing precise refined specifications for the components. Trends in automotive industry were analysed and specifications were developed according to the most promising technological solutions (high voltage battery, unification of the component base, wide bandgap power semiconductors, and high-speed technology).
Electrical machine, which can operate at high speed, provides more power than a low speed machine having the same dimensions. High-speed machines are more compact for a given output mechanical power. However, some obstacles are arising with higher speeds as cooling, noise, vibration, and harshness (NVH), centrifugal forces, bearings. Numerical optimization techniques were used to minimize mass, torque ripple, and costs and to maximize energy efficiency in the same time. Fast switching SiC-modules of the converter support the increasing of power density of electrical motors.
The electrical motor was developed with maximum speed of 20000 rpm with specific power of 3.4 kW/kg, Which is significantly higher compared to the solutions on the market. The peak efficiency of the motor is around 97%.
The main task of the converter was to control power flow between the electrical machine and a primary energy source, e.g. a battery. A high-speed electrical machine as a part of the integrated solution needs a high frequency power supply. Novel SiC components was used in order to ensure robust operation even at elevated frequencies. Moreover, SiC components are foreseen as the upcoming mass-market components for the most efficient drives. Usage of high voltage 800 V with SiC fast switching inverter provided the inverter power density of 42 kW/l and efficiency above 98%.
In order to provide flexibility for mass manufacturing of the vehicles utilizing the concept of distributed drive, all components were integrated within one compact and lightweight frame sharing the same cooling circuit. The module was interfaced with vehicle’s thermal management system, battery, wheel drive and vehicle control system. This should significantly simplify the installation for the car manufactures and reduce the amount of components and raw material used.