The paper contains a review of recent advancements in rotating machines with bulk high-temperature superconductors (HTS). The high critical current density of bulk HTS enables us to design rotating machines with a compact configuration in a practical scheme. The development of an axial-gap-type trapped flux synchronous rotating machine together with the systematic research works at the Tokyo University of Marine Science and Technology since 2001 are briefly introduced. Developments in bulk HTS rotating machines in other research groups are also summarized. The key issues of bulk HTS machines, including material progress of bulk HTS, in situ magnetization, and cooling together with AC loss at low-temperature operation are discussed.
We studied a high-temperature superconducting synchronous motor assembled with melt-textured Gd-Ba-Cu-O bulk field magnets. The motor is an axial gap-type, brushless synchronous motor with eight rotating bulk field magnet poles. Liquid nitrogen is circulated to cool down the rotor components. Pulsed field magnetization was performed to excite the bulk field magnets by using a pair of the vortex-type armature copper windings under the zero-field cooling. The trapped peak field density on the surface of the bulk was varied from 0.5 T to 0.8 T. The trapped peak magnetic field 0.5 T on the surface of the bulk magnets provided the motor performance of 3.1 kW with 720 rpm. The field density distribution on the pole bulk magnet surface is anisotropic and different from the ideal conical shape. The optimized pulsed current waveform applied to the armature and the employing of a composite of bulk crystal magnets leading to a spatially homogeneous flux trapping are promising methods for reinforcement of the field flux from the rotor and the motor torque.Index Terms-High-temperature super-conducting motor, hightemperature superconductors, melt-processed bulk superconductors, melt-textured Gd123.
Rotating machines with high-temperature superconductors (HTS) usually consist of
pole-field magnets having coils wound with Bi-2223 HTS wire. We have successfully used
Gd–Ba–Cu–O bulk HTS in pole-field magnets in an axial-gap type rotating machine. These
HTS pole-field bulk magnets were assembled in the rotor plate. They are cooled down with
a liquid cryogen supplied via a rotary joint and circulated inside the rotor plate. The
present design provides a small air gap and a bulk HTS gives a high magnetic field around
the armature coils. Successful mechanical design has enabled us to magnetize the pole-field
bulk to more than 1 T by using a pulsed current applied to the copper armature coils.
These techniques imply the possibility of smaller and lighter rotating motors or generators
with a HTS bulk magnet for a sub-megawatt class propulsion system. We report several
essential techniques for both mechanical and cryogenic designs, and deduce the
characteristic features of the present axial-gap type machine using a HTS bulk magnet.
The present manuscript addresses key issues in the course of our study of materials processing of bulk high-temperature superconductors, trapped flux and its application to a prototype axial-gap-type rotating machine. The TUMSAT group has conducted a series of studies since 2003 on the growth of GdBa2Cu3O7−δ bulk material and its application in a compact low-speed high-torque rotating machine. In the stage of material growth, gaining the advantage of a large motive torque density requires large integrated flux in the motor/generators. A large grain surface might be required with sophisticated techniques for the melt-growth texture in the bulk with optimal flux pinning. In the second stage, the in situ magnetization procedure for bulk superconductors in the applied machine is a crucial part of the technology. Pulsed current excitation by using an armature copper winding has magnetized field pole bulks on the rotor. The axial-gap flux synchronous machine studied in the past decade is a condensed technology and indicates that further scientific development is required for a future compact machine to be superior to conventional ones in accordance with the cryogenic periphery and flux stabilization.
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