Comparison of Different Configurations for Shoreline Pond Electrode Station for HVDC Transmission Systems—Part I: Electric Field Study for Frames of Linear Electrode Arrangement Based on a Simplified Analytical Model
-
Published:2023-06-14
Issue:12
Volume:13
Page:7136
-
ISSN:2076-3417
-
Container-title:Applied Sciences
-
language:en
-
Short-container-title:Applied Sciences
Author:
Kontargyri Vassiliki T.12ORCID, Tsekouras George J.12ORCID, Prousalidis John M.3ORCID, Tsirekis Costantinos D.4, Leontaritis Konstantinos4, Alexandris John C.4, Kanellos Fotis D.5, Deligianni Panagiota M.14, Kontaxis Panagiotis A.12ORCID, Moronis Antonios X.1ORCID
Affiliation:
1. Department of Electrical and Electronics Engineering, University of West Attica, 250 Thivon Str., 12241 Athens, Greece 2. School of Electrical and Computer Engineering, National Technical University of Athens, Heroon Polytechniou 9, 15780 Athens, Greece 3. School of Naval Architecture and Marine Engineering, National Technical University of Athens, Heroon Polytechniou 9, 15780 Athens, Greece 4. Hellenic Indepedent Power Transmission Operator, Dyrrachiou 89 & Kifissou, 10443 Athens, Greece 5. School of Electrical and Computer Engineering, Technical University of Crete, University Campus, Akrotiri, 73100 Chania, Greece
Abstract
During the design of a shoreline electrode station for High-Voltage Direct Current (HVDC) interconnections, the location of the electrodes plays a critical part, especially in the development of the near-electric field. The basic structure is their linear placement, in the form of successive frames, parallel to the longitudinal axis of the breakwater, as proposed by CIGRE and implemented in existing projects. However, this arrangement requires a considerable breakwater length, which may not be permissible, as in the case of Stachtoroi, one of the two electrode stations being built for the 1 GW, ±500 kV HVDC interconnection between Crete and mainland Greece. This troubled the preliminary study team of the electrode stations, which investigated other possible configurations. In this paper, configurations of linear placements of electrode frames are studied and compared at the preliminary study level in terms of electric field effects (especially the near-field), using an analytical simplified model and the superposition method, to determine the most appropriate arrangement of electrodes that will cover the respective requirements of CIGRE directives B4.61/2017. These arrangements are practically evaluated for two different electrode station locations at Korakia in Crete and at Stachtoroi in Aegina for the Crete–mainland-Greece interconnection, resulting in interesting alternative solutions.
Subject
Fluid Flow and Transfer Processes,Computer Science Applications,Process Chemistry and Technology,General Engineering,Instrumentation,General Materials Science
Reference35 articles.
1. CIGRE Working Group B4.61 (2017). General Guidelines for HVDC Electrode Design, CIGRE. [1st ed.]. 2. Tsekouras, G.J., Kontargyri, V.T., Prousalidis, J.M., Kanellos, F.D., Tsirekis, C.D., Leontaritis, K., Alexandris, J.C., Deligianni, P.M., Kontaxis, P.A., and Moronis, A.X. (2022). Alternative Simplified Analytical Models for the Electric Field, in Shoreline Pond Electrode Preliminary Design, in the Case of HVDC Transmission Systems. Energies, 15. 3. Independent Power Transmission Generator S.A. (2018). Technical Description for Shoreline Electrodes for HVDC Link Attica-Creta, Independent Power Transmission Generator S.A.. [3rd ed.]. 4. A cost comparison of metallic and earth return path for HVDC transmission System case study: Connection Algeria-Europe;Bouzid;Electr. Power Syst. Res.,2019 5. Hatch-Statnett (2008). Newfoundland and Labrador Hydro-Lower Churchill Project-DC1110 Electrode Review-Gull Island & Soldiers Pond, Hatch-Statnett. [1st ed.]. Muskrat Falls Project-CE-09 Rev.1.
|
|