Dynamic simulation of simultaneous HVDC contingencies relevant for vulnerability assessment of the nordic power system

2019 IEEE Milan PowerTech Pub Date : 2019-06-23 DOI:10.1109/PTC.2019.8810863

Espen Hafstad Solvang, I. B. Sperstad, S. H. Jakobsen, K. Uhlen

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引用次数: 4

Abstract

Large power-infeed of individual HVDC interconnectors may make the power system vulnerable to contingencies involving multiple HVDC interconnectors. This paper describes and demonstrates an approach to quantitative vulnerability analysis applied to HVDC contingencies. We consider four barriers' ability to mitigate severe frequency drops: inertial response, frequency containment reserves, demand-side response and under-frequency load shedding. Demand-side response, implemented as fast reduction in loads in response to decreasing frequency, is given particular attention. The consequences of an HVDC contingency in the presence or absence of these barriers is analysed to assess the power system vulnerability. Results illustrate how in low-inertia operating states, a) large-scale load shedding may be inevitable after simultaneous outage occurrence of multiple HVDC interconnectors and b) that barriers may significantly reduce the amount of load shed. Demand-side response could be an effective barrier if the response time is low and a sufficiently large amount of load is involved.

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与北欧电力系统脆弱性评估相关的高压直流事故同步动态模拟

单个高压直流互连线的大功率输入可能使电力系统容易受到涉及多个高压直流互连线的突发事件的影响。本文描述并演示了一种应用于高压直流事故的定量脆弱性分析方法。我们考虑了减轻严重频率下降的四个障碍的能力:惯性响应、频率遏制储备、需求侧响应和低频负载减少。需求方面的响应，即随着频率的下降而迅速减少负荷，得到了特别的关注。在存在或不存在这些障碍的情况下，分析高压直流事故的后果，以评估电力系统的脆弱性。结果表明，在低惯性运行状态下，a)多个HVDC互连器同时停电后，大规模减载可能是不可避免的;b)屏障可能显著减少减载量。如果响应时间较短且涉及足够大的负荷，需求侧响应可能是一个有效的障碍。

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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2019 IEEE Milan PowerTech

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