Computational approach to enhance performance of photovoltaic system inverters interfaced to utility grids

Arzani, Ali; Venayagamoorthy, G.K.

doi:10.1049/iet-rpg.2016.1044

Cited by 18 publications

(11 citation statements)

References 36 publications

(46 reference statements)

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“…A large PV plant of capacity 210 MW is installed at Bus 12, a 230 kV utility transmission grid bus in Area-2 of the power system [25]. Real-time weather profiles, solar irradiance (Irr(t)) and temperature (T emp(t)) are used to emulate the PV plant generation.…”

Section: B Pv Power Plantmentioning

confidence: 99%

Resilient and Sustainable Tie-Line Bias Control for a Power System in Uncertain Environments

Jayawardene

Venayagamoorthy

Zhong

2022

IEEE Trans. Emerg. Top. Comput. Intell.

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Section: B Pv Power Plantmentioning

confidence: 99%

Resilient and Sustainable Tie-Line Bias Control for a Power System in Uncertain Environments

Jayawardene

Venayagamoorthy

Zhong

2022

IEEE Trans. Emerg. Top. Comput. Intell.

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“…A two‐level VSI, using the current control sine pulse‐width modulation technique, controls the PV power flow to grid. The detailed PV‐inverter parameter settings and control algorithms in compliance with an established control strategy are adopted from [51, 52]. To compensate for the two integrated PV plants, both area 1 and area 2 loads are increased another 175 MW at buses 16 and 24; and 240 MW at buses 33 and 45.…”

Section: Multi‐area Power System With Multiple Agcsmentioning

confidence: 99%

Optimal automatic generation controllers in a multi‐area interconnected power system with utility‐scale PV plants

2019

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The centralised utility-scale photovoltaic (PV) plants installation has greatly enlarged their percentage in the bulk power systems, along with the nature uncertainty for the balance of system power and loads. Consequently, the successful integration of solar PV power in large-scale power systems requires a reliable and efficient multi-area automatic generation control (AGC) system within the control centre. Specifically, area-AGCs that perform tie-line bias control, in which the area frequency regulates the tie-line power flow, must balance the operational control area supply power-and-demand loads within a pre-tuned parameter set. Traditional AGC control systems have area linear controllers that must be periodically tuned to manage the high fluctuation of PV power. A practical two-step tuning method to determine the optimal parameters of existing multi-area AGCs is presented. The proposed method is demonstrated on a five-area multi-machine power system with two large PV plants. The power system was equipped with the synchrophasor-based monitoring system, with a real-time simulation platform serving as the application host. Results indicated that the two-step tuning method provides optimal parameters for all the system AGCs over a wide range of PV penetration levels. Typical results demonstrated the effectiveness of the tuned multiarea AGCs under dynamic conditions and disturbances.

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“…Voltage Source Inverters (VSIs) are widely utilized for integration of Distributed Generation units (DGs) including Renewable Energy Resources (RESs) to distribution systems and Microgrids (MG) [1][2][3][4][5][6]. The control approaches of the VSIs in an MG can be classified to Current and Voltage Control Modes (CCM and VCM) depending on the prime-mover type of DGs [7].…”

Section: Introductionmentioning

confidence: 99%

Secondary‐control‐based harmonics compensation scheme for voltage‐ and current‐controlled inverters in islanded microgrids

Mousavi

Jalilian

Savaghebi

et al. 2020

IET Renewable Power Generation

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Computational approach to enhance performance of photovoltaic system inverters interfaced to utility grids

Cited by 18 publications

References 36 publications

Resilient and Sustainable Tie-Line Bias Control for a Power System in Uncertain Environments

Resilient and Sustainable Tie-Line Bias Control for a Power System in Uncertain Environments

Optimal automatic generation controllers in a multi‐area interconnected power system with utility‐scale PV plants

Secondary‐control‐based harmonics compensation scheme for voltage‐ and current‐controlled inverters in islanded microgrids

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