Islanding Detection for Inverter-Based Distributed Generation Using Unsupervised Anomaly Detection

Arif, Adeel; Imran, Kashif; Cui, Qiushi; Weng, Yang

doi:10.1109/access.2021.3091293

Cited by 15 publications

(6 citation statements)

References 52 publications

(58 reference statements)

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“…The optimal gain K f is directly proportional to the quality factor of the load; however, when the quality factor is more than five, K f will be too large to create a false detection and can even cause system instability. The authors in [88] proposed a Q g −f droop curve method to keep K f to a safe value and monitor the change of frequency for islanding detection. During normal operation, the reactive power is controlled by the grid; however, during islanding operation, since the DG units operate at unity power factor and produce no reactive power, this creates a frequency difference between the actual and the rated system frequency.…”

Section: Hybrid Sandia Frequency Shift and Q G −F Methodsmentioning

confidence: 99%

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Islanding Detection Methods for Microgrids: A Comprehensive Review

et al. 2021

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Microgrids that are integrated with distributed energy resources (DERs) provide many benefits, including high power quality, energy efficiency and low carbon emissions, to the power grid. Microgrids are operated either in grid-connected or island modes running on different strategies. However, one of the major technical issues in a microgrid is unintentional islanding, where failure to trip the microgrid may lead to serious consequences in terms of protection, security, voltage and frequency stability, and safety. Therefore, fast and efficient islanding detection is necessary for reliable microgrid operations. This paper provides an overview of microgrid islanding detection methods, which are classified as local and remote. Various detection methods in each class are studied, and the advantages and disadvantages of each method are discussed based on performance evaluation indices such as non-detection zone (NDZ), detection time, error detection ratio, power quality and effectiveness in multiple inverter cases. Recent modifications on islanding methods using signal processing techniques and intelligent classifiers are also discussed. Modified passive methods with signal processing and intelligent classifiers are addressing the drawbacks of passive methods and are getting more attention in the recently published works. This comprehensive review of islanding methods will provide power utilities and researchers a reference and guideline to select the best islanding detection method based on their effectiveness and economic feasibility.

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Section: Hybrid Sandia Frequency Shift and Q G −F Methodsmentioning

confidence: 99%

“…This works by combining the rate of change of frequency and voltage methods to detect islanding [88]. The rate of change of voltage and the rate of change of frequency at the PCC are monitored as a first step to detect if one of them exceeds the predefined threshold to indicate islanding might have occurred.…”

Section: Voltage Fluctuation Injectionmentioning

confidence: 99%

Islanding Detection Methods for Microgrids: A Comprehensive Review

et al. 2021

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“…The existing approaches confronted the islanding detection problem in modern grid-tied networks in a comprehensive manner. However, the existing research has some limitations: (i) Noisy measurements are not considered in some of the existing islanding detection schemes [15,36]; (ii) some of the islanding detection strategies have a very high computational burden [22][23][24][25][26][27][28][29][30][31][32][33]; (iii) threshold setting in some schemes is difficult to implement [15,21]; and (iv) NDZ is large in few passive schemes, especially during low power miss-match moreover, some islanding detection indexes get failed [17,20].…”

Section: Limitations Of Existing Schemesmentioning

confidence: 99%

“…The index was developed based on the rate of change of frequency (ROCOF) of the DG. The authors in [15] presented an unsupervised anomaly detection to detect islanding events in the distribution network. The ROCOF and the phase angle of the voltage/current were used as the first and second detection parameter respectively.…”

Section: Introductionmentioning

confidence: 99%

1D recursive median filter based passive islanding detection strategy for grid‐connected distributed generations network

Mumtaz

Imran

Rehman

et al. 2023

IET Renewable Power Gen

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In modern distribution networks, integration of distributed generations (DGs) at consumer premises is common. However, islanding detection in such a grid‐tied distributed generation (GTDG) network is the topmost challenge to ensure power quality and reliable operation. This paper presents a modified passive islanding detection scheme (MPIDS) for the GTDG network, using a One‐D recursive Median filter (ODRMF) algorithm. Firstly, at the point of common coupling (PCC), 3‐phase voltage is acquired. Next, the ODRMF is employed to extract 3rd harmonic and residuals from the acquired voltage signal. Afterward, two novel islanding detection indices developed are: (1) First change detection (FCD), which is calculated from the residuals, and (2) delta selected harmonic distortion (∆SHD), which is computed from 3rd harmonic content of the voltage signal. Finally, variations in the two indices are compared with the threshold to identify islanding. To validate the efficacy of the presented MPIDS, rigorous simulations in MATLAB/ Simulink are conducted on the UL‐1741 and IEEE 13‐bus GTDGs systems under different conditions. The results illustrate that the presented strategy is highly reliable in all assessed conditions and can detect the islanding as well as non‐islanding incidents effectively under balanced and unbalanced load/generation conditions with a very low non‐detection zone.

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“…If the fault occurs on the utility grid side which is outside of the PCC and then DER remains supplied to the fault along with the utility grid [96]. During external fault (islanding) conditions, islanding detection should occur and the microgrid should be isolated from the utility grid area through PCC because fault current flowing in the reverse direction from the microgrid DER towards the fault point which is located at the utility grid area to protect the microgrid equipment [97], [98].…”

Section: ) Islanding Conditionmentioning

confidence: 99%