Navegando por Autor "SOUZA, Vanderson Carvalho de"
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Dissertação Acesso aberto (Open Access) Controle local de potência reativa em geradores fotovoltaicos para a melhoria da regulação de tensão em redes de distribuição(Universidade Federal do Pará, 2017-03-31) SOUZA, Vanderson Carvalho de; VIEIRA, João Paulo Abreu; http://lattes.cnpq.br/8188999223769913This dissertation addresses the major operational problems faced by distribution network operators due to the high integration of photovoltaic (PV) generators, such as overvoltages, excessive tap counts and voltage regulator runaway condition. The overvoltage problem in distribution networks may be caused by significant active power injection from PV generation. Additionally, the rapid and significant variations in PV generator active power associated with cloud transients result in an increase of voltage regulator tap counts, adversely affecting the useful life of that device. Also, when the direction of the power flow is reversed due to PV generator active power injection, the voltage regulator can fail to control voltage at the regulated bus and reach lowest or highest tap limit (runaway condition). This dissertation proposes a local reactive power control for PV inverters to alleviate such problems. The proposed control is evaluated using measurement data from the real rooftop PV system in the city of Belém and dynamic simulations on a single MV feeder with a PV solar plant.Tese Acesso aberto (Open Access) Inibidor bidirecional de eventos de runaway no comutador de tap de reguladores de tensão em redes de distribuição reconfiguráveis com geração distribuída(Universidade Federal do Pará, 2024-06-25) SOUZA, Vanderson Carvalho de; VIEIRA, João Paulo Abreu; http://lattes.cnpq.br/8188999223769913Climate change has intensified over the years, especially as a result of the global energy model that is predominantly based on the use of fossil fuels. Thus, there is an urgent need to boost a low-carbon economy as a response to the climate crisis. In this context, renewable energy sources emerge as the main alternative to fossil fuels. However, the integration of these sources into distribution networks can cause voltage control problems resulting from bidirectional power flow in such networks. An important voltage control problem is the phenomenon known as tap changer runaway condition in step-voltage regulators (SVRs). Nowadays, the problem is further challenging in reconfigurable distribution networks with renewable energy sources connected to both the source-side and load-side of the SVR. This problem occurs when the SVR control cannot adequately distinguish the origin of the active power flow through the SVR and tries to control the voltage on the side of the network with the highest short circuit capacity (strong side), causing under or overvoltage on the side of the network with the lowest short circuit capacity. short circuit (weak side). Current solutions to mitigate the runaway problem are mainly based on three categories: 1) voltage control support by distributed generation (DG); 2) use of remote measurements/information; and 3) use of local measurements/information. However, considering practical aspects, only solutions in the third category are feasible. Even so, these solutions are restricted to application for inhibiting the runaway condition caused exclusively by reverse power flow. In this Thesis, an algorithm is proposed for robust local bidirectional on-line inhibition of the runaway condition based only on a test tap switching with robustness guarantees and without the need for switching of tap test coordinate in cascaded SVRs. The main contributions of the Thesis are the innovative application of the algorithm in robust local bidirectional on-line inhibition of the runaway condition in the tap switch and the introduction to industrial insights. The accuracy and robustness of the proposed algorithm are verified through time series power flow simulations carried out on two test networks, with noise and gross errors in measurements, using extensive Monte Carlo simulations. The uncoordinated operation of test tap switching in cascaded SVRs is examined through case studies on a long real rural distribution network. Finally, the effect of photovoltaic (PV) source variability on the performance of the proposed algorithm is evaluated. The results obtained confirmed the effectiveness of the proposed algorithm in bidirectional inhibition of the runaway condition