地电海岸效应对地磁感应电流的影响

IF 3.8 2区工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Power Delivery Pub Date : 2025-02-21 DOI:10.1109/TPWRD.2025.3544488

Darcy R. Cordell;Martyn J. Unsworth

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引用次数: 0

摘要

电网中的地磁感应电流（gic）会损坏变压器，引起电压不稳定并导致停电。传输线中的感应电压是由与传输线平行的感应表面地电场分量驱动的。众所周知，一个导电的海洋可以增加海岸向陆地一侧的地电场强度。然而，在阐明邻近海洋如何影响网络gis方面所做的工作有限。我们使用一个位于海洋附近的著名网络模型来模拟gic。与沿海地区GIC风险较高的观念相反，我们表明，相对于排除海岸影响的计算GIC，海洋可能导致沿海电网中最大可能GIC的减少，而海洋导致的GIC的增加可能相对温和。这是因为地电场只在垂直于海岸的分量中增加，而在平行于海岸的分量中减少。因此，与海岸线平行的输电线路在其整个长度上经历了感应电压的净下降，而垂直于海岸线的输电线路经历了感应电压的增加，但受距离海岸的距离的限制。

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The Influence of the Geoelectric Coast Effect on Geomagnetically Induced Currents

Geomagnetically induced currents (GICs) in power networks can damage transformers, cause voltage instability and lead to power outages. GICs are driven by an induced voltage in transmission lines due to the induced surface geoelectric field component parallel to the line. It is well-known that an electrically conductive ocean can increase the geoelectric field magnitude on the landward side of the coast. However, limited work has been done to elucidate how the adjacent ocean impacts network GICs. We model GICs using a well-known network model situated adjacent to an ocean. Contrary to the notion that GIC risk is higher in coastal areas, we show that the ocean can cause a decrease in the maximum possible GIC in coastal power networks relative to calculated GICs which exclude coast effects, while increases in GIC due to the ocean can be relatively modest. This is because the geoelectric field only increases in the component perpendicular to the coast but decreases parallel to the coast. Thus, transmission lines parallel to coastlines experience a net decrease in induced voltage along their entire length, while transmission lines perpendicular to coastlines experience an increase in induced voltage that is self-limited by the distance from the coast.

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来源期刊

IEEE Transactions on Power Delivery 工程技术-工程：电子与电气

CiteScore

9.00

自引率

13.60%

发文量

513

审稿时长

6 months

期刊介绍： The scope of the Society embraces planning, research, development, design, application, construction, installation and operation of apparatus, equipment, structures, materials and systems for the safe, reliable and economic generation, transmission, distribution, conversion, measurement and control of electric energy. It includes the developing of engineering standards, the providing of information and instruction to the public and to legislators, as well as technical scientific, literary, educational and other activities that contribute to the electric power discipline or utilize the techniques or products within this discipline.