Voltage regulation during short-circuit faults in low voltage distributed generation systems

• Published in: Electric power systems research Vol. 234; p. 110596
• Main Authors: Döhler, Jéssica S., Eriksson, Robert, Oliveira, Janaína G., Boström, Cecilia
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.09.2024
• Subjects: Ancillary services; Fault detection; Grid-supporting inverter; Low-voltage system; Short circuit; Voltage support; Low-voltage system; Short circuit; Fault detection; Voltage support; Grid-supporting inverter; Ancillary services
• ISSN: 0378-7796; 1873-2046
• DOI: 10.1016/j.epsr.2024.110596

As the penetration of inverter-based distributed generations into microgrids continues to rise, the significance of power electronic inverters in modern power systems becomes increasingly pronounced. They are designed to have fault ride-through capabilities, enabling them to sustain operation even during and after fault conditions. This paper presents a novel voltage compensation strategy based on the line impedances addressing both positive and negative-sequence aspects, for a three-phase three-wire inverter deployed to regulate the low-voltage network during unsymmetrical faults, thereby preserving voltage stability. The control strategy is carried out in a synchronous reference frame (dq) to govern the positive and negative-sequence voltages and currents of the inverter. By synthesizing AC currents, the inverter restores the positive-sequence voltage to its rated value while mitigating negative-sequence voltage at the point of common coupling arising from unsymmetrical faults. Through MATLAB/Simulink, are investigated three unsymmetrical fault scenarios (single line-to-ground, line-to-line, and double line-to-ground faults) within the low-voltage distribution network of the 18-bus European Cigré, incorporating three inverters equipped with the proposed voltage support capability. The results confirm that inverter-interfaced distributed generators with local voltage support can improve the system’s fault ride-through capability by reducing voltage drops and unbalances. •Voltage resilience in the face of short-circuit challenges.•Balancing voltage fluctuations during grid faults.•Grid-supporting inverters optimize fault response.