Dustin Kottonau scite author profile

Along with advancements in superconducting technology, especially in high temperature superconductors (HTS), the use of these materials in power system applications is gaining outstanding attention. Due to the lower weight, higher current carrying capability, and the lower loss of HTS cables compared to conventional counterparts, they are among the most focused applications of superconductors in power systems. In near future, these cables will be installed as key elements not only in power systems but also in cryo-electrified transportation units, which take advantage of both cryogenics and superconducting technology simultaneously, e.g. hydrogen-powered aircraft. Given the sensitivity of the reliable and continuous performance of HTS cables, any failures, caused by faults, could be catastrophic, if they are not designed appropriately. Thus, fault analysis of superconducting cables is crucial for ensuring their safety, reliability, and stability, and also for characterising the behaviour of HTS cables under fault currents at the design stage. Many investigations were conducted on the fault characterisation and analysis of HTS cables in the last few years. This paper aims to provide a topical review on all of these conducted studies, It will discuss the current challenges of HTS cables and after that current developments of fault behaviour of HTS cables would be presented, and then we will discuss the future trends and future challenges of superconducting cables regarding their fault performance.

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An open-source 2D finite difference based transient electro-thermal simulation model for three-phase concentric superconducting power cables

Sousa

Shabagin

Kottonau

et al. 2020

Supercond. Sci. Technol.

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Advances in superconductor technology make the prospect of economical operation of high temperature superconducting (HTS) power cables a practical concept for grid applications in urban centers. With more advanced cable designs being developed and commercialized, their geometrical features and dynamic behavior are becoming increasingly complicated to be modeled. This brings new challenges as the complex structure of HTS power cables significantly increases the computation power needed to perform simulations. In this paper we develop a two-dimensional open source simulation code based on the finite difference method which is solved by means of the alternating direction implicit routine. The algorithm has been written in MatLab programming language. The method improves computational performance and simulation time. In addition, this enables the creation of open-source simulation codes. A three-phase concentric HTS cable design has been chosen for the development of the code, nevertheless the model can be employed for any cable design. The results indicate an efficient, stable and powerful simulation code. During the development no numerical instabilities have been found. Besides that, the model is able to deliver quantities that are experimentally difficult to access. Simulation files are available for the scientific community on the HTS Modeling Workgroup webpage. 1 1 Simulation files can be downloaded.here.

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Investigation of a Concentric Three-Phase HTS Cable Connected to an SFCL Device

Sousa

Kottonau

Böck³

et al. 2018

IEEE Trans. Appl. Supercond.

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Design Comparisons of Concentric Three-Phase HTS Cables

Kottonau

Sousa

Böck³

et al. 2019

IEEE Trans. Appl. Supercond.

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Dustin Kottonau

Transient Simulation and Recovery Time of a Three-Phase Concentric HTS Cable

High temperature superconducting cables and their performance against short circuit faults: current development, challenges, solutions, and future trends

An open-source 2D finite difference based transient electro-thermal simulation model for three-phase concentric superconducting power cables

Investigation of a Concentric Three-Phase HTS Cable Connected to an SFCL Device

Design Comparisons of Concentric Three-Phase HTS Cables

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