Implementation of variable gain controller based improved phase locked loop approach to enhance power quality in autonomous microgrid

Kundu, Sombir; Singh, Madhusudan; Giri, Ashutosh

doi:10.1002/jnm.3082

Cited by 13 publications

(2 citation statements)

References 42 publications

(90 reference statements)

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“…However, these types of DGs are only reliable and productive in grid-connected mode when the national grid power is adequate [2,3]. Islanding detection requires special attention because unintentional islanding is one of the most dangerous situations in such GCDGNs [4][5][6][7]. Unintentional islanding phenomena arise when the national grid supply is cut off from the DGs as a result of any fault or switching events, hence posing severe safety and protection troubles [8,9].…”

Section: Motivation and Problem Statementmentioning

confidence: 99%

Triple‐indexed passive islanding detection strategy for grid‐connected distributed generation networks using an extended Kalman filter

Larik,

Li,

2024

IET Generation Trans & Dist

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Islanding detection is a challenging issue in modern grid‐connected distributed generation networks (GCDGN). Generally, islanding detection has two categories local and remote, local schemes can be categorized into active, passive, and hybrid schemes. This article proposes a triple‐indexed passive islanding detection (TIPID) scheme using an extended Kalman filter (EKF). Initially, the EKF algorithm is applied on voltage signal at the point of the common coupling to estimate the desired fundamental and non‐fundamental features. The first index, known as the cumulative voltage logarithmic index, is computed by taking the natural logarithm of the fundamental voltage features to detect any variations in the GCDGN. The second index, known as the voltage differentiation index (VDI), is calculated from the fundamental voltage features, while the third index, known as the odd‐order harmonic distortion index (OOHDI), is obtained from the non‐fundamental odd‐order harmonics of the PCC voltage. Then, the VDI and OOHDI are compared to pre‐defined threshold to detect/distinguish islanding events. The proposed TIPID method is validated through extensive simulations on the IEEE 13‐bus test bed via MATLAB/Simulink 2022b. Results show that under both balanced/unbalanced load & generation, the proposed TIPID approach detects islanding occurrences with reduced non‐detection zone (NDZ) in less than 5 ms.

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Section: Motivation and Problem Statementmentioning

confidence: 99%

Triple‐indexed passive islanding detection strategy for grid‐connected distributed generation networks using an extended Kalman filter

Larik,

Li,

2024

IET Generation Trans & Dist

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“…A multiloop frequency controller augmented with fractional‐order calculus with in‐depth qualitative analysis for smart grid has been presented 1,2 . The challenging area in EV charging stations with PV array and distribution network, 3 optimal power flow with renewables integrated smart grid, 4 security assessment of grid‐connected society during grid failure or blackouts, 5 resilient power quality control framework for an autonomous microgrid, 6 and detection of false data injection attacks in smart grid 7 have been addressed to cope with challenging issues in smart grid operation/control continuum.…”

mentioning

confidence: 99%

Special issue on: AI/data‐based modeling, control, and operation of smart grid power systems

Arya

Guha

Sarangi

2023

Int J Numerical Modelling

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Implementation of an adaptive control approach in a single‐phase grid‐tied solar photovoltaic system for power quality improvement

Singh,

Rai

2024

Circuit Theory & Apps

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SummaryThis work focuses on a novel single‐phase complex band‐pass filter‐based frequency‐locked loop (1ϕ‐CBF‐FLL) control for a grid‐tied solar photovoltaic array (SPVA)‐based energy generating system. Among the novel characteristics of this 1ϕ‐CBF‐FLL control algorithm are as follows: (1) It offers a quick convergence rate; (2) it has the ability to mitigate harmonics and DC offset; and (3) it has simplicity in execution. A voltage source converter (VSC), boost converter, 1‐ϕ grid, ripple filter, and nonlinear loads are all part of the system. Feeding 1‐ϕ nonlinear loads and the grid with active power from the solar array is managed by the VSC. Furthermore, grid current quality is enhanced by the use of VSC. Between the solar array and DC‐link capacitor, there is a boost converter that uses the perturb and observe (P&O) technique to track the maximum power from the SPVA. The primary aim of the proposed system is to remove power quality (PQ) issues brought on by nonlinear and imbalanced loads and to supply sinusoidal grid currents during solar irradiance fluctuations. Additionally, a comparison between 1ϕ‐CBF‐FLL control and other control algorithms is presented. The effectiveness of this 1ϕ‐CBF‐FLL control is examined under varying nonlinear loads and in various environmental settings. Test results are used to confirm the simulated results of the proposed system. According to the IEEE‐519 standard, the recommended control may achieve a source current of total harmonic distortion (THD) of 4.02%, which is lower than 5%, a source voltage of THD of 3.21%, and a load current of THD of 24.54%.

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Implementation of variable gain controller based improved phase locked loop approach to enhance power quality in autonomous microgrid

Cited by 13 publications

References 42 publications

Triple‐indexed passive islanding detection strategy for grid‐connected distributed generation networks using an extended Kalman filter

Triple‐indexed passive islanding detection strategy for grid‐connected distributed generation networks using an extended Kalman filter

Special issue on: AI/data‐based modeling, control, and operation of smart grid power systems

Implementation of an adaptive control approach in a single‐phase grid‐tied solar photovoltaic system for power quality improvement

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