Within the last years magnetic bearing technology has been pushed by a significant upturn in oil & gas industry as well as in machining applications. Nowadays, specific high speed spindles are equipped with industrially standardized active magnetic bearing systems (AMB) allowing for highly precise rotor positioning due to their contact-free and low-maintenance operation. However, compared to conventional ball bearings well-established AMB systems are limited by their relatively low stiffness. In order to improve dynamic performance flux based control algorithms have been suggested for the last decades already. The main challenge is how to integrate commercially available magnetic field sensors into the tiny air gap of typically 500 micro meter. Therefore, ultra-thin and preferably even flexible sensor elements meeting the strong requirements in lifetime and reliability are essentially needed. Within this project ultra-thin Bismuth Hall sensors with a total thickness of less than 150 micro meter are under development. After fabrication the sensor functionality and suitability for detection of time-varying magnetic fields in AMB systems are to be investigated intensely. Finally the sensor signal is intended to be used as directly integrated feedback for flux based AMB control strategies. Besides Hall sensorics precise rotor positioning strongly demands fast switching converters operated with high pulse frequencies (50 kHz) in order to achieve both accurate flux density/current control as well as a high bandwidth of the carrier frequency based position measurement system. Therefore, fast switching Gallium-Nitride-FETs (GaN) will be used for an H-bridge-converter powering the AMB coils. By using GaN-FETs a fast switching converter featuring substantially reduced dead times and low conduction losses can be realized.

DFG Programme Research Grants

International Connection Austria

Cooperation Partners Professor Dr. Manfred Albrecht; Professor Dr.-Ing. Martin Kaltenbrunner; Dr.-Ing. Michael Löser; Dr. Denys Makarov