posted on 2016-12-08, 14:18authored byXiuchang Zhang, H. S. Ruiz, Jianzhao Geng, T. A. Coombs
This paper presents a novel method to determine the optimal strategy for the allocation of multiple resistive superconducting
fault current limiters (SFCLs) aiming to improve the overall protection of standard power grids. The
presented approach allows for the straightforward determination of the optimal resistance of the SFCL, accounting
for short circuit events occurring at different locations, by modelling the electro-thermal properties of the SFCL via a
temperature dependent E-J power law. This material law, based on previous experimental evidence, allows for the introduction
of flux pinning, flux creep, and flux flow properties of the superconducting material within a minimum level
of complexity. Thereby, we have observed a distinctive kink pattern in the current limiting profiles of the SFCLs, from
which no further reduction of the first peak of the fault current is achieved when a greater resistance is considered,
allowing a univocal determination of the optimum SFCL resistance. This peculiarity is not observed when the model
for the quench properties of the SFCL is simplified towards an exponential resistance, although the last can be used as
an auxiliary process for addressing the first guess on the resistance value required for a specific strategy, as it demands
less computing time. We have also determined that for many of the cases studied, i.e, for the combinations between
one or more SFCLs installed at different locations, and those subjected to fault events located at different points in
the network, the recovery time of the superconducting properties of at least one of the SFCLs can last for more than
five minutes, constraining the feasibility of a large-scale deployment of this technology. However, by assuming that
the practical operation of the SFCL is assisted by the automatic operation of a bypass switch when the SC material
is fully quenched, we have determined that the optimal strategy for the overall protection of power grids of standard
topology requires a maximum of three SFCLs, with recovery times of less than a few seconds. This information is of
remarkable value for power system operators, as it can establish a maximum investment threshold which ultimately
can facilitate making decisions regarding the deployment of SFCL technologies.
Funding
This work was supported by the Engineering and
Physical Sciences Research Council (EPSRC) project
NMZF/064. X. Zhang acknowledges a grant from the
China Scholarship Council (No. 201408060080).
History
Citation
International Journal of Electrical Power and Energy Systems, 2017, 87, 136–143
Author affiliation
/Organisation/COLLEGE OF SCIENCE AND ENGINEERING/Department of Engineering
Version
AM (Accepted Manuscript)
Published in
International Journal of Electrical Power and Energy Systems
PACS: 84.71.-b, 85.25.Am, 88.05.Bc, 88.05.Ec, 88.05.Lg, 88.80.Cd, 88.80.H, 88.50.Mp;The file associated with this record is under embargo until 12 months after publication, in accordance with the publisher's self-archiving policy. The full text may be available through the publisher links provided above.