Identify Resonant Frequencies in AC Distribution Networks – A Numerical Example Part I – Harmonic Nodal Admittance Matrix Method

Pană, Adrian; Baloi, Alexandru

doi:10.1016/j.sbspro.2015.04.369

Cited by 2 publications

(2 citation statements)

References 3 publications

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“…The combined system of such elements, for example, in a substation, produces a power system with a resonant frequency (also known as the “natural” or “critical” frequency) dependant on the elements in the system. Such resonances can be identified by the application of nodal admittance matrix analysis (e.g., Amornvipas & Hofmann, 2010; Huang et al., 2007; Pană & Băloi, 2014). This analysis involves the generation of an N by N Nodal Admittance matrix, where N is the number of busses in the system being analyzed.…”

Section: Discussionmentioning

confidence: 99%

Even‐Order Harmonic Distortion Observations During Multiple Geomagnetic Disturbances: Investigation From New Zealand

Crack,

Rodger,

Clilverd

et al. 2024

Space Weather

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Large geomagnetic storms are a space weather hazard to power transmission networks due to the effects of Geomagnetically Induced Currents (GICs). GIC can negatively impact power transmission systems through the generation of even‐order current and voltage harmonics due to half‐cycle transformer saturation. This study investigates a decade of even‐order voltage total harmonic distortion (hereon referred to as Even‐Order Total Harmonic Distortion (ETHD)) observations provided by Transpower New Zealand Ltd., the national system operator. We make use of ETHD measurements at 139 locations throughout New Zealand, monitored at 377 separate circuit breakers, focusing on 10 large geomagnetic disturbances during the period 2013–2023. Analysis identified 5 key substations, which appeared to act as sources of ETHD. The majority of these substations include single phase transformer banks, and evidence of significant GIC magnitudes. The ETHD from the source substations was found to propagate into the surrounding network, with the percentage distortion typically decaying away over distances of 150–200 km locally, that is, at a rate of −0.0043 %km−1. During the study period some significant changes occurred in the power network, that is, removal of the Halfway Bush (HWB) single phase bank transformer T4 in November 2017, and decommissioning of the New Plymouth substation in December 2019. Decommissioning of these two assets resulted in less ETHD occurring in the surrounding regions during subsequent geomagnetic storms. However, ETHD still increased at HWB with increasing levels of GIC, indicating that three phase transformer units were still susceptible to saturation, albeit with about 1/3 of the ETHD percentage exhibited by single phase transformers.

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Section: Discussionmentioning

confidence: 99%

Even‐Order Harmonic Distortion Observations During Multiple Geomagnetic Disturbances: Investigation From New Zealand

Crack,

Rodger,

Clilverd

et al. 2024

Space Weather

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“…In this approach, the interconnection is represented by a nodal-admittance matrix as a multi-input multi-output system, in which the matrix elements are transfer functions. However, up to date, this admittance matrix have only represented the lumped parameters of conventional pisection models of lines [15], [20], [21].…”

Section: Interoperability Studiesmentioning

confidence: 99%

Analytical methodology to develop frequency-dependent equivalents in networks with multiple converters

Bayo-Salas

Beerten

Hertem

2017

2017 IEEE Manchester PowerTech

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This paper discusses the analysis of dynamic interactions above the fundamental frequency in networks with high penetration of converters. For this purpose, interaction studies require a good representation of network resonances and converter dynamics. However, current methodologies present some limitations in this respect. On one hand, the harmonic impedance obtained from the frequency scan in software does not consider the influence of converter control dynamics. On the other hand, typical stability studies consider those at the cost of simplifying the network representation. The increasing penetration of converters in the network arises concerns due to their limitation in accurately capturing the instability. This paper demonstrates the impact of control interactions in a meshed network with several converters and how this interaction influences the network resonances. Due to the limitations of existing methods, the paper presents a systematic method to capture the relevant dynamic phenomena.

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Identify Resonant Frequencies in AC Distribution Networks – A Numerical Example Part I – Harmonic Nodal Admittance Matrix Method

Cited by 2 publications

References 3 publications

Even‐Order Harmonic Distortion Observations During Multiple Geomagnetic Disturbances: Investigation From New Zealand

Even‐Order Harmonic Distortion Observations During Multiple Geomagnetic Disturbances: Investigation From New Zealand

Analytical methodology to develop frequency-dependent equivalents in networks with multiple converters

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