FCL: A solution to fault current problems in DC networks

Within the context of the electric power market liberalization, DC networks have many interests compared to AC ones. New energy landscapes open the way of a diversified production. Innovative interconnection diagrams, in particular using DC buses, are under development. In this case it is not possib...

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Bibliographic Details
Published inJournal of physics. Conference series Vol. 97; no. 1; p. 012062
Main Authors Cointe, Y, Tixador, P, Villard, C
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 01.02.2008
Subjects
Alternating current
Circuits
Conductors
Critical temperature
Current limiters
Direct current
Electrical insulation
Homogeneity
Low temperature
Numerical models
Physics
Power amplifiers
Sensors
Short circuit currents
Shunt resistance
Substrates
Temperature
Thermal analysis
Thermal conductivity
Thermal resistance
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Summary:Within the context of the electric power market liberalization, DC networks have many interests compared to AC ones. New energy landscapes open the way of a diversified production. Innovative interconnection diagrams, in particular using DC buses, are under development. In this case it is not possible to defer the fault current interruption in the AC side. DC fault current cutting remains a difficult problem. FCLs (Fault Current Limiters) enable to limit the current to a preset value, lower than the theoretical short-circuit current. For this application Coated Conductors (CC) offer an excellent opportunity. Due to these promising characteristics we build a test bench and work on the implementation of these materials. The test bench is composed by 10 power amplifiers, to reach 4 kVA in many configurations of current and voltage. We carried out limiting experiments on DyBaCuO CC from EHTS, samples are about five centimeters long and many potential measuring points are pasted on the shunt to estimate the quench homogeneity. Thermal phenomena in FCLs are essential, numerical models are important to calculate the maximum temperatures. To validate these models we measure the CC temperature by depositing thermal sensors (Cu resistance) above the shunt layer and the substrate. An electrical insulation with a low thermal resistivity between the CC and the sensors is necessary. We use a thin layer of Parylene because of its good mechanical and electrical insulation properties at low temperature. The better quench behaviour of CC for temperatures close to the critical temperature has been confirmed. The measurements are in good agreement with simulations, this validates the thermal models.
ISSN:1742-6596
1742-6588
1742-6596
DOI:10.1088/1742-6596/97/1/012062