INERTIAL OSCILLATION CONTROL FOR HIGH PENETRATION OF WIND GENERATION SYSTEMS
DOI:
https://doi.org/10.34019/2179-3700.2022.v22.37915Keywords:
Load frequency control. Wind generation. Virtual synchronous generator. Reverse response. Hydro generation.Abstract
This work presents a methodology to solve the problem related to low inertia due high penetration of wind generation in electric power system. The objective is to include wind generation in the Load-Frequency Control (LFC) through the technique of virtual synchronous generator. Therefore, the primary frequency control associated with the overspeed operation of wind turbines are implemented considering the power exchange with hydro power plant. The results obtained show that this technique is effective to increase the inertia of the system reducing the frequency variations, the inverse response of hydraulic turbines and oscillations in the interchange lines.
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DA SILVA, Gabriel S. et al. Load frequency control and tie-line damping via virtual synchronous generator. International Journal of Electrical Power & Energy Systems, v. 132, p. 107108, 2021.
FERREIRA, Bruna C. et al. Comparação de Metaheurísticas para o Ajuste Ótimo do Controle de Frequência em Sistemas Interligados com Geração Eólica. In: Simpósio Brasileiro de Automação Inteligente-SBAI. 2021.
FU, Yuan et al. Active participation of variable speed wind turbine in inertial and primary frequency regulations. Electric Power Systems Research, v. 147, p. 174-184, 2017.
LOPES, Vanessa S.; BORGES, Carmen LT. Impacto da Complementaridade entre Geração Eólica e Hidráulica na Confiabilidade Composta. Anais do SBSE 2012-IV Simpósio Brasileiro de Sistemas Elétricos, p. 1-6.
MAGDY, Gaber et al. Renewable power systems dynamic security using a new coordination of frequency control strategy based on virtual synchronous generator and digital frequency protection. International Journal of Electrical Power & Energy Systems, v. 109, p. 351-368, 2019.
Matlab Documentation Center. Optimization toolbox, constrained optimization, fmincon. 2020.
OLIVEIRA, Edimar J. et al. Optimal transient droop compensator and PID tuning for load frequency control in hydro power systems. International Journal of Electrical Power & Energy Systems, v. 68, p. 345-355, 2015.
ONS. http://www.ons.org.br/paginas/resultados-da-operacao/historico-da-operacao/dados-gerais, 2022.
SHABANI, Hamed; VAHIDI, Behrooz; EBRAHIMPOUR, Majid. A robust PID controller based on imperialist competitive algorithm for load-frequency control of power systems. ISA transactions, v. 52, n. 1, p. 88-95, 2013.
Simulink Documentation. Simulation and model-based design, 2020.
TESSARO, Heitor José; DE OLIVEIRA, Ricardo Vasques. Impact assessment of virtual synchronous generator on the electromechanical dynamics of type 4 wind turbine generators. IET Generation, Transmission & Distribution, v. 13, n. 23, p. 5294-5304, 2019.
ZHANG, Weichao; YAN, Xiangwu; HUANG, Hanyan. Performance tuning for power electronic interfaces under VSG control. Applied Sciences, v. 10, n. 3, p. 953, 2020.
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Copyright (c) 2022 Gabriel Schreider da Silva, Edimar José de Oliveira, Lucas Campos dos Santos Souza
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