Direct current technologies for Switzerland's electricity transmission and distribution

Carpita, Mauro (School of Management and Engineering Vaud, HES-SO // University of Applied Sciences Western Switzerland) ; Razzaghi, R. (Ecole Polytechnique Fédérale de Lausanne, Electromagnetic Compatibility Laboratory (EPFL EMC), Lausanne, Switzerland) ; Wang, Z. (Ecole Polytechnique Fédérale de Lausanne, Electromagnetic Compatibility Laboratory (EPFL EMC), Lausanne, Switzerland) ; Paolone, M. (Ecole Polytechnique Fédérale de Lausanne, Electromagnetic Compatibility Laboratory (EPFL EMC), Lausanne, Switzerland) ; Rachidi, F. (Ecole Polytechnique Fédérale de Lausanne, Electromagnetic Compatibility Laboratory (EPFL EMC), Lausanne, Switzerland) ; Dujic, D. (Ecole Polytechnique Fédérale de Lausanne, Power Electronics Laboratory (EPFL PEL), Lausanne, Switzerland) ; Christe, A. (Ecole Polytechnique Fédérale de Lausanne, Power Electronics Laboratory (EPFL PEL), Lausanne, Switzerland) ; Milovanovic, S. (Ecole Polytechnique Fédérale de Lausanne, Power Electronics Laboratory (EPFL PEL), Lausanne, Switzerland) ; Utvic, M. (Ecole Polytechnique Fédérale de Lausanne, Power Electronics Laboratory (EPFL PEL), Lausanne, Switzerland) ; Galland, Olga (School of Engineering and Architecture (HEIA-FR), HES-SO // University of Applied Sciences Western Switzerland) ; Allani, Mohamed (School of Engineering and Architecture (HEIA-FR), HES-SO // University of Applied Sciences Western Switzerland) ; Favre-Perrod, Patrick (School of Engineering and Architecture (HEIA-FR), HES-SO // University of Applied Sciences Western Switzerland) ; Schultz, T. (Eidgenössische Technische Hochschule Zürich, High Voltage Laboratory) ; Franck, C. M. (Eidgenössische Technische Hochschule Zürich, High Voltage Laboratory) ; Tsolaridis, G. (Hochschule Zürich, High Power Electronic Systems (ETHZ HPE)) ; Biela, J. (Hochschule Zürich, High Power Electronic Systems (ETHZ HPE))

Existing AC power systems, established more than a century ago, are increasingly challenged by DC technologies, enabled by significant advancements in the power electronics and related scientific fields. Three major application areas for DC transmission are established: transferring bulk power over long distances, interconnecting grids and connecting offshore wind. Medium and low voltage DC application become more appealing based on the improved controllability, more effective integration of renewable energy sources, higher power density and better compatibility with underground cables. Such technologies will be attractive for the Swiss energy transition as they might provide more effective solutions for the densification of power systems, the integration of converter-based renewable energy sources and pumped-storage plants. In order to achieve this, several research challenges however need to be overcome and standardization must further advance. Several academic partners from Switzerland contribute to these research problems in WP3: “Multi-Terminal AC-DC Grids and Power Electronics” within the SCCER FURIES. In this paper six major topics are presented: - “General overview of DC options” where present and future applications of DC technologies as wells as MVDC grids development issues are discussed. - “MMC-based MVDC converters” where selection of modular multilevel converter as a platform in order to provide flexibility in addressing multitude of applications and conversion needs is shown. Several topological adaptations are proposed, leading to novel converter topologies. - “AC/DC resonance analysis” where analysis allowing to find the resonance location and to analyze resonance nodes contribution to critical mode. These frequency analysis methods permit to foresee network frequency behavior that is becoming important issue due to growing number of power electronics converters in the network. - “Overview of HVDC breaker technologies” where basic requirements for fast and reliable HVDC circuit breakers as well as the differences to HVAC technology are introduced. - “HVDC circuit breakers: testing methods and challenges” where the limits of HVDC circuit breakers are explored. In this section, a flexible, modular high current source is presented. The source is intended to act as a hardware-in-the-loop test bench for future HVDC circuit breakers, by driving highly dynamic and arbitrary current waveforms through dynamic loads (e.g. DC arc). - “Fault location principles” where the significant influence of fault location on the network security of supply and quality is drawn. A newly-developed technique which is based on the electromagnetic time reversal (EMTR) theory that can be applied to radial/meshed AC/DC power transmission or distribution networks is presented and compared to other Travelling Wave – based methods. The outputs and outlooks are drawn in order to conclude the paper.


Note: SCCER - Furies ; Swiss Confederation ; Innosuisse (Swiss Innovation Agency)


Faculty:
Ingénierie et Architecture
School:
HEIG-VD
Institute:
IESE - Institut d'Energie et Systèmes Electriques
Publisher:
Switzerland, Future Swiss Electrical Infrastructure (SCCER-FURIES) ; Swiss Innovation Agency (Innosuisse)
Date:
2019-03
Switzerland
Future Swiss Electrical Infrastructure (SCCER-FURIES) ; Swiss Innovation Agency (Innosuisse)
Pagination:
32 p.
DOI:
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 Record created 2019-07-16, last modified 2019-07-16

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