Estratégias de controle para operação de microrredes isoladas.

Abstract

This work focuses on the proposal and validation of control strategies for simultaneous regulation of voltage and frequency in isolated Microgrid, voltage harmonics compensation in the common coupling point and the reactive power of cooperation between the different inverters installed in the Microgrid (MG). The used control technique is the modified generalized Droop control to meet the design needs (energy flow operation trafficked in MG), maintaining the balance between generation and consumption with rapid, safe, efficient and stable. In this scenario, six control strategies have been proposed and validated for different scenarios tests (linear and nonlinear loads) and topologies MG (1 bar, 3 bars, 5 bars, 11 bars and 14 bars) which are: conventional GDC, ANFIS GDC, GDC Fuzzy Adaptive GDC, GDC and PI Fuzzy Cooperative with virtual impedance. The methodology used consisted of the following steps: A) literature review; B) choice of MG tests (IEEE standard); C) modeling and simulation of the constituent parts of an isolated MG; D) design of the control strategies used in the MG operation; E) Validation of control strategies; F) Technical discussion of the simulation results and G) Elaboration of technical documents. Faced with the control strategies implemented, the GDC Adaptive controller showed the best dynamic performance in closed loop (fast response time, small fluctuations of voltage and frequency, low sensitivity to fluctuations in load and energy source, making the control robustness and stable). When assisted by internal loops, it achieves reactive power cooperation and harmonic compensation in the face of apparent power fluctuations in both consumption and generation. The proposed solutions for simultaneous regulation of voltage and frequency in isolated MG, harmonic voltage compensation in the PCC and reactive power sharing between the connected inverters in the MG were efficient when evaluated in several test scenarios and for several MG topologies in terms of stable MG operation, maintaining the balance between generation and consumption, responding quickly to the operational variations, load disturbances and nonlinearities of the islanded MG.