Development and Test of a Small Resistive Fault Current Limiting Device Based on a SmBaCuO Ceramic

Carlos Auguto Cardoso Passos; Marcos Tadeu D'azeredo Orlando; Juliana N.O. Pinto; Vinicius Toneto Abilio; Jnaína B. Depianti; Arthur Cavichini; Luiz Carlos Machado

doi:10.4028/www.scientific.net/AMR.975.173

Paper Titles

Particle-Filled Polysilazane Coatings for Steel Protection
p.149

Effects of Microwave Processing on the Properties of Nickel Oxide/Zirconia/Ceria Composites
p.154

Effect of Cd Doping on Mechanical Properties of SrCoO₃
p.163

Electrical Properties of a TiO₂-SrO Varistor System
p.168

Development and Test of a Small Resistive Fault Current Limiting Device Based on a SmBaCuO Ceramic
p.173

Electrodeposition of Zinc Oxide on Graphene Tips Electrochemically Exfoliated and O₂-Plasma Treated
p.179

Dielectric Properties of CaCu₃Ti₄O₁₂ Synthesized by Different Routes
p.184

Gas Sensor Properties of ZnO Nanorods Grown by Chemical Bath Deposition
p.189

A Capacitive-Type Humidity Sensor Using Porous Ceramics for Environmental Monitoring
p.194

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 975Development and Test of a Small Resistive Fault...

Development and Test of a Small Resistive Fault Current Limiting Device Based on a SmBaCuO Ceramic

Abstract:

Since the development of Low Critical Temperature Superconducting (low-Tc) materials, various studies have been published regarding this experimental concept. Recently, researchers have focused on the design and application of high-Tc superconductor (high-Tc) materials to develop fault current limiting circuit breakers. The operation of this circuit requires large prospective/limited current ratios, especially in hazardous areas. In spite of this, several studies describing the Superconducting Fault Current Limiter (SFCL) containing members of the bismuth, mercury or yttrium family cuprate have already been described. However, none of these studies included samarium cuprates. Consequently, we have conducted a study of a small superconducting current limiter device based on SmBa₂Cu₃O_7-d samples. The preliminary results indicated that samarium cuprates could be applied to build superconducting fault current limiter devices. In tests using a polycrystalline sample, the superconducting properties were retained without modifications to its stoichiometry. These results suggest the possibility of future investigations into SFCL devices based on these superconducting ceramics. Keywords: High-Tc, Sm-123, Device, Fault current limiter.

You might also be interested in these eBooks

View Preview

View Preview

Info:

Periodical:

Advanced Materials Research (Volume 975)

Pages:

173-178

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.975.173

Citation:

Cite this paper

Online since:

July 2014

Authors:

Carlos Auguto Cardoso Passos*, Marcos Tadeu D'azeredo Orlando, Juliana N.O. Pinto, Vinicius Toneto Abilio, Jnaína B. Depianti, Arthur Cavichini, Luiz Carlos Machado

Keywords:

Fault Current Limiter, High-Tc, Sm-123

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] K. Ueda, O. Tsukamoto, S. Nagaya, H. Kimura and S. Akita, IEEE Trans. Appl. Supercond. 13 (2003) 1946-195.

Google Scholar

[2] S. Elschner, F. Breuer, M. Noe, T. Rettelbach, H. Walter, J. Bock, IEEE Trans. Appl. Supercond. 12 (2002) 1980-(1983).

DOI: 10.1109/tasc.2003.812954

Google Scholar

[3] M. Chen, W. Paul. M. Lakner, L. Donzel, M. Hoidis, P. Unternaehrer, R. Weder, M. Medik, Physica C 372-376 (2002) 1657-1663.

DOI: 10.1016/s0921-4534(02)01096-1

Google Scholar

[4] E.M. Leung, A. Rodriguez, B. Burley, M. Dew, P. Gurrola, D. Madura, G. Miyata, K. Muehleman, L. Nguyen, S. Pidcoe, S. Ahmed, G. Dishaq, C. Nieto, I. Kersenbaum, B. Gamble, C. Russo, H. Boenig, D. Peterson, L. Motowildo, P. Haldar, IEEE Trans. Appl. Supercond. 7 (1997).

DOI: 10.1109/77.614670

Google Scholar

[5] C.A.C. Passos, M.T. Orlando, J.L. Passamai, E.F. Medeiros, F.D. Oliveira, J.F. Fardin, D.S.L. Simonetti, Appl. Phys. Lett. 89 (2006) 242503.

DOI: 10.1063/1.2408637

Google Scholar

[6] C.A.C. Passos, J.L. Passamai Jr., M.T.D. Orlando, E.F. Medeiros, R.V. Sampaio, F.D.C. Oliveira, J.F. Fardin, D.S.L. Simonetti, Physica C 460-462 (2007) 1451-1452.

DOI: 10.1016/j.physc.2007.04.148

Google Scholar

[7] H. Suematsu, M. Kawano, T. Onda, T. Akao, M. Hayakawa, H. Ogiwara b, M. Karppinena, H. Yamauchi, Physica C 324 (1999)161-171.

DOI: 10.1016/s0921-4534(99)00462-1

Google Scholar

[8] C.A.C. Passos, M.T.D. Orlando, F.D.C. Oliveira, P.C.M. da Cruz, J.L. Passamai Jr., C.G.P. Orlando, N.A. Eloi, H.P.S. Correa, L.G. Martinez, Supercond. Sci. Technol. 15 (2002) 1177-1183.

DOI: 10.1088/0953-2048/15/8/301

Google Scholar

[9] A. Sin, L. Fabrega, M.T.D. Orlando, A.G. Cunha, S. Pinol, E. Bagio-Saitovich, X. Obradors, Physica C 328 (1999) 80-88.

DOI: 10.1016/s0921-4534(99)00550-x

Google Scholar

[10] C.A.C. Passos, M.T.D. Orlando, A.A.R. Fernandes, F.D.C. Oliveira, D.S.L. Simonetti, J.F. Fardin, H. Belichand, M.M. Ferreira Jr., Physica C 419 (2005) 25-31.

Google Scholar

[11] F.D.C. Oliveira, C.A.C. Passos, J.F. Fardin, D.S.L. Simonetti, J.L. Passamai Jr., H. Belich, E. F. de Medeiro, M.T.D. Orlando, M.M. Ferreira Jr., IEEE Trans. Appl. Supercond. 16 (2005) 15-20.

DOI: 10.1109/tasc.2005.861062

Google Scholar

[12] M.T.D. Orlando, C.A.C. Passos, J.L. Passamai Jr, E.F. Medeiros, C.G.P. Orlando, R.V. Sampaio, H.S.P. Correa, F.C.L. de Melo, L.G. Martinez, J.L. Rossi, Physica C 434 (2006) 53.

DOI: 10.1016/j.physc.2005.11.016

Google Scholar

[13] J. Maňka, A. Cigáň, J. Polovková, A. Koňakovský, A. Prnová, Measurement Sci. Rev. 11 (2011) 10-14.

DOI: 10.2478/v10048-011-0005-2

Google Scholar

[14] S. Nemdili, S. Belkhiat, J. Supercond. Nov. Magn. 26 (2013) 2713-2720.

Google Scholar