Abstract
Friction and heat generated in conventional bearings impose a limit on maximum design speed in electrical machines. Superconducting bearings offer the potential for low loss, simplified, and passively stable bearings that can overcome the speed limit and operate at high loads. Although such bearings are contactless and seem to be loss free, AC loss mainly caused by magnetic field inhomogeneity gradually slows down the rotating body. This loss, whose mechanism has not been fully explored, is measured through spin-down tests where the rotational speed of the spinning rotor is measured as a function of time. However, there are some challenges in performing a reliable spin-down test. In this paper, we discuss these challenges as well as the engineering of an experimental test rig that enables us to spin-up, release, and recapture the levitated permanent magnet. We also discuss the specifications of the driving mechanism including the self-aligning coupling, which accommodates permanent magnets of different sizes. Initial test results at 6600 rpm are discussed and further technical improvements to the test rig suggested. This rig will be used as a key tool to explore the AC loss mechanism and inform the design of bearings for high-speed superconducting machines.
Highlights
The output power of an electrical machine is proportional to both rotational frequency and rotor excitation field [1]
The friction and heat generated by conventional bearings limit the design speed of any electrical machine
The z-component of the magnetic field from a PM 17 mm in diameter and 10 mm thick was mapped over a 3D volume at room temperature
Summary
The output power of an electrical machine is proportional to both rotational frequency and rotor excitation field [1]. The friction and heat generated by conventional bearings limit the design speed of any electrical machine. Active magnetic bearings [2,3,4] and superconducting magnetic bearings [5,6,7] have been widely investigated as possible solutions to overcome this speed barrier. Magnetic bearings require active position controllers to maintain the stability of the system. This can add complexity to the bearing system design. Superconducting magnetic bearings offer passive stable levitation/suspension through th flux pinning feature of type-II superconductors [5]
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