Processing of Bulk MgB2 Superconductors for Application in Fault Current Limiters

Tatiana Prikhna; Vladimir Sokolovsky; Victor Meerovich; Michael Eisterer; Athanasios G. Mamalis; Artem Kozyrev; Wolfgang Gawalek; Viktor Moshchil; Vladimir Sverdun; Harald W. Weber; Valeriy Kovylaev; Wilfried Goldacker; Myroslav Karpets; Tatiana Basyuk; Min Zhi Wu; Nina Sergienko

doi:10.4028/www.scientific.net/MSF.856.32

Paper Titles

Behavior of both Nonmagnetic Particles and Magnetic Particles in Magnetic Compound Fluids in a Micro-Tube with Axial Flow under Rotating Magnetic Field
p.9

Dynamic Interfacial Phenomena at Water-Magnetic Fluid System Subject to Alternating Magnetic Field
p.15

Vibrating Properties of a Magnetic-Fluid Tuned Liquid Column Damper with Different U-Pipes
p.21

Characteristics in the Opening and Closing Operations of Micro Magnetic Fluid Diaphragm Mechanism by Alternating Magnetic Field
p.26

Processing of Bulk MgB₂ Superconductors for Application in Fault Current Limiters
p.32

Brushless Exciter Based on Nanomaterials for 1 MVA HTSC Wind Power Alternator
p.38

Amorphous Alloy Cores for HTSC Electrical Devices
p.44

New Developments of Mesoscopic Materials of Nano-Scale Particles for Optical and Dielectric Applications
p.53

Generalized Thin-Wire Hybrid VFETD/FDTD Schemes for Nanocomposite and Graphene Applications
p.58

HomeMaterials Science ForumMaterials Science Forum Vol. 856Processing of Bulk MgB2 Superconductors for...

Processing of Bulk MgB₂ Superconductors for Application in Fault Current Limiters

Abstract:

Fault current limiters (FCL) require superconducting (SC) materials which can provide a definite rate of response to a fault event resulting in the SC – normal state reversible transition. The main characteristics determined the material suitability are the critical current density, j_c, thermal conductivity and capacity which are strongly determined by manufacturing technology, in particular, of MgB₂. In the paper we estimate the j_c of bulk MgB₂ samples by the vibrating magnetometer and inductive, contactless transformer, method using ring samples. The bulk MgB₂ samples were produced under 30 MPa (hot pressing) and 2 GPa (quasihydrostatic pressing) at 800-1050 ^оС from different initial ingredients (Mg and B or MgB₂ with and without additions). It is shown that the technology process and initial ingredients strongly influence the distribution of boron-and oxygen-enriched nanosized inhomogenities in MgB₂ matrix, connectivity between SC grains, material porosity and, as result, the SC properties. The transformer method gives the j_c in the range from 1.6·10⁴ up to 6.3·10⁴ A/cm² at about 4 K while using magnetometer measurements the j_c is estimated from 2.24·10⁵ up to 5.1·10⁵ A/cm² at 10 K in self-magnetic fields. The contradictions in the j_c estimated by different methods can be explained by instability of the SC state of MgB₂, caused by variation of the applied magnetic field. Using the transformer method AC losses per a cycle before quenching for the best materials were estimated around 0.75-1 J/cm³, while the power of losses was about 200 W. The FCL model with rings cut out from SC MgB₂ materials prepared using various technologies demonstrated that MgB₂ is a promising material for application in inductive FCLs.

You might also be interested in these eBooks

Applied Electromagnetic Engineering for Advanced Materials from Macro- to Nanoscale

View Preview

Info:

Periodical:

Materials Science Forum (Volume 856)

Pages:

32-37

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.856.32

Citation:

Cite this paper

Online since:

May 2016

Authors:

Tatiana Prikhna*, Vladimir Sokolovsky, Victor Meerovich, Michael Eisterer, Athanasios G. Mamalis, Artem Kozyrev, Wolfgang Gawalek, Viktor Moshchil, Vladimir Sverdun, Harald W. Weber, Valeriy Kovylaev, Wilfried Goldacker, Myroslav Karpets, Tatiana Basyuk, Min Zhi Wu, Nina Sergienko

Keywords:

Bulk MgB₂, Critical Current Density, Fault Current Limiter, Nanostructure, Pressure

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] V. Meerovich, V. Sokolovsky, T. Prikhna, W. Gawalek, and T. Habisreuther. Supercond. Sci. Technol., Vol. 26, (2013), 035015 (8pp).

DOI: 10.1088/0953-2048/26/3/035015

Google Scholar

[2] N. E. Reimann, R. Cherkaoui, B. Dutoit, D. Djukic, and G. Grasso. IEEE Trans. Appl. Superconduct., Vol. 7, (1997), p.836.

Google Scholar

[3] V. Meerovich, V. Sokolovsky, G. Jung, and S. Goren. Applied Superconductivity 1995, Inst. Phys. Conf. Series., Vol. 148, (1995), p.603.

Google Scholar

[4] T.A. PRIKHNA, M. EISTERER, H.W. WEBER, W. GAWALEK, V.V. KOVYLAEV, M.V. KARPETS, T.V. BASYUK AND V.E. MOSHCHIL. SUPERCOND. SCI. TECHNOL. VOL. 27, (4), (2014), P. 044013 (9PP).

DOI: 10.1088/0953-2048/27/4/044013

Google Scholar

[5] Т. A. Prikhna, М. Eisterer, W. Goldacker,W. Gawalek,V. Sokolovsky, H. W. Weber, A. V. Kozyrev, V. E. Moshchil, V. B. Sverdun, V. V. Kovylaev, M. V. Karpets, T. V. Basyuk, and A. V. Shaternik, IEEE Trans. Appl. Superconduct., Vol. 25, (3), (2015).

DOI: 10.1109/tasc.2013.2237736

Google Scholar

[6] T. Prikhna, M. Eisterer, W. Gawalek, V. Sokolovsky, A. Kozyrev, V. Moshchil, H. W. Weber, S. Dub, X. Chaud, V. Kovylaev, V. Sverdun, M. Karpets, T. Basyuk, N. Sergienko, and T. Serbeniuk, Advances in Science and Technology, Vol. 95, (2014), p.156.

DOI: 10.4028/www.scientific.net/ast.95.156

Google Scholar

[7] T. PRIKHNA, M. EISTERER, W. GAWALEK, A. MAMALIS, A. KOZYREV, V. KOVYLEAV, E. HRISTOFOROU, H.W. WEBER, J. NOUDEM, W., GOLDAKER, V., MOSHCHIL, X. CHAUD, V. SOKOLOVSKY, A. SHATERNIK, J. DELLITH, CH. SCHMIDT, T. HABISREUTHER, D. LITZKENDORF, S. DUB, A. BORIMSKIY. MATERIALS SCIENCE FORUM , VOL. 792, (2014).

DOI: 10.4028/www.scientific.net/msf.792.21

Google Scholar