Using a Differential Magnetometer Technique to Measure Geomagnetically Induced Currents: An Augmented Approach

Space Weather Pub Date : 2024-07-01 DOI:10.1029/2024sw003894

H. Parry, I. Mann, A. Kale, D. Milling, C. Clark, R. Cui, D. Cordell, M. Unsworth

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Abstract

Geoelectric fields produced by time‐varying magnetic fields during geomagnetic storms can result in potentially damaging geomagnetically induced currents (GICs) in long conductors at the Earth's surface. GICs can pose a significant risk to the integrity of grounded electrical infrastructure, particularly high‐voltage transformers. In this study, an inferred GIC is calculated using an augmented differential magnetometer measurement (DMM) technique on a 500 kV transmission line in central Alberta and is validated using a proximal transformer neutral‐to‐ground (TNG) current measurement by AltaLink L.P. using a Hall probe at a transformer substation. This research outlines a custom‐built and innovative DMM design by which both DMM sensors deployed around a power line measure the background geomagnetic disturbance (GMD) field and the magnetic field generated locally by the GIC. We show how this modified approach provides two independent estimates for GIC derived using only ΔBy or ΔBz, the magnetic field components perpendicular to the line carrying GIC. Results for a geomagnetic storm on 12 Oct 2021 show contemporaneous peaks in the TNG current and the DMM‐inferred GIC. The two data sets have similar waveforms and are within the same order of magnitude. The background GMD is reconstructed using DMM and shows excellent correlation to the measured GMD at the permanent Canadian Array for Real‐time Investigations of Magnetic Activity magnetic station at Ministik Lake, approximately 48.5 km away. Based on the results presented here, we verify the added utility value of DMM for temporary deployments for assessing GIC risk in electrical power grids.

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使用差分磁力计技术测量地磁诱导电流：一种增强方法

地磁暴期间时变磁场产生的地电场会在地球表面的长导体中产生具有潜在破坏性的地磁感应电流（GIC）。地磁感应电流会对接地电气基础设施，尤其是高压变压器的完整性构成重大风险。在这项研究中，使用增强型差分磁力计测量 (DMM) 技术对阿尔伯塔省中部的一条 500 千伏输电线路进行了推断 GIC 计算，并使用 AltaLink L.P. 公司在变电站使用霍尔探头进行的近端变压器中性点对地 (TNG) 电流测量进行了验证。这项研究概述了一种定制的创新型 DMM 设计，通过这种设计，部署在电力线周围的两个 DMM 传感器都能测量背景地磁扰动 (GMD) 场和 GIC 在本地产生的磁场。我们展示了这种改进方法如何提供两个独立的 GIC 估计值，这两个估计值仅使用与携带 GIC 的线路垂直的磁场分量 ΔBy 或 ΔBz。2021 年 10 月 12 日地磁风暴的结果显示，TNG 电流和 DMM 推算的 GIC 出现了同期峰值。两组数据的波形相似，量级相同。使用 DMM 重建的背景 GMD 与位于 Ministik 湖（约 48.5 公里）的永久性加拿大磁活动实时调查阵列磁站测量的 GMD 显示出极好的相关性。根据本文介绍的结果，我们验证了 DMM 在临时部署评估电网 GIC 风险方面的附加实用价值。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Space Weather

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