Increased Impedance of Wound HTS Power Cables by Quenching at a Shielding Layer for Fault Current Limiting Function

The use of high temperature superconducting (HTS) power cables is viable solution to address the growing demand for electric power, while ensuring low loss and high electric power transmission. Usually, HTS power cables and circular connection of substations reduce grid impedance, and the fault current is increased over the capacity of the circuit breaker. To protect the electric power grid, the fault current should be reduced below the allowable level. Of late, research on HTS power cables having fault current limiting (FCL) functions has increased. An inductive FCL HTS power cable uses the increased inductive impedance caused by magnetic flux leakage to a neighboring iron yoke when a quench occurs at the shielding layer of the cable core due to electromagnetic coupling with the conducting layer. Therefore, there is less heat generation, and the temperature rise is suppressed. In this study, we describe the increased inductive impedance and reduced fault current using a FCL model coil. To demonstrate the electromagnetic coupling between the conducting and shielding layers of the cable core, two concentrically wound REBCO coils were fabricated. The iron yoke inside the coil increases the inductive impedance when a fault current flows through the conducting layer, and quench occurs at the shielding layer. The results are used to develop an FCL HTS power cable with 154 kV, 600 MVA class.

[1]  Mohsen Niasati,et al.  On the advance of SFCL: a comprehensive review , 2019, IET Generation, Transmission & Distribution.

[2]  Bertrand Raison,et al.  Technical and Economic Analysis of the R-Type SFCL for HVDC Grids Protection , 2017, IEEE Transactions on Applied Superconductivity.

[3]  Masaru Tomita,et al.  FCL Effect of DC Superconducting Cables in Unsteady State , 2017, IEEE Transactions on Applied Superconductivity.

[4]  Sung-Kwan Joo,et al.  Economic Evaluation Method for Fault Current Limiting Superconducting Cables Considering Network Congestion in a Power System , 2016, IEEE Transactions on Applied Superconductivity.

[5]  Ya Wei Wang,et al.  Inductance evaluation of a 22.9 kV/50 MVA HTS cable with shield by electrical method , 2015, 2015 IEEE International Conference on Applied Superconductivity and Electromagnetic Devices (ASEMD).

[6]  Byoung-Sung Han,et al.  Study on Verification for the Realizing Possibility of the Fault-Current-Limiting-Type HTS Cable Using Resistance Relation With Cable Former and Superconducting Wire , 2015, IEEE Transactions on Applied Superconductivity.

[7]  Min Zhang,et al.  Inductance and Current Distribution Analysis of a Prototype HTS Cable , 2014 .

[8]  Min Jee Kim,et al.  The application of fault current limiter at Icheon substation in Korea , 2011, 2011 1st International Conference on Electric Power Equipment - Switching Technology.

[9]  M. Kurrat,et al.  Influence of Bubble Formation on the Dielectric Behavior of Liquid Nitrogen , 2011, IEEE Transactions on Applied Superconductivity.

[10]  Y Xin,et al.  Performance of the 35 kV/90 MVA SFCL in Live-Grid Fault Current Limiting Tests , 2011, IEEE Transactions on Applied Superconductivity.

[11]  Marjan Popov,et al.  Transient Analysis of a 150 kV Fault Current Limiting High Temperature Superconducting Cable , 2011 .

[12]  T. Masuda,et al.  The Results of Installation and Preliminary Test of 22.9 kV, 50 MVA, 100 m Class HTS Power Cable System at KEPCO , 2007, IEEE Transactions on Applied Superconductivity.

[13]  Charles K. Alexander,et al.  Fundamentals of Electric Circuits , 1999 .