Design and implementation of a droop control in d-q frame for islanded microgrids

The droop control method is usually selected when several distributed generators (DGs) are connected in parallel forming an islanded microgrid. This is because of the advantages it offers such as flexibility, absence of critical communications etc. Besides, several studies add a fictitious impedance...

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Bibliographic Details
Authors: Planas Fullaondo, Estefanía, Gil-de-Muro, Asier, Andreu Larrañaga, Jon, Kortabarria Iparragirre, Iñigo, Martínez de Alegría Mancisidor, Iñigo
Format: article
Publication Date:2013
Country:España
Institution:Universidad del País Vasco
Repository:Addi. Archivo Digital para la Docencia y la Investigación
OAI Identifier:oai:addi.ehu.eus:10810/64805
Online Access:http://hdl.handle.net/10810/64805
Access Level:Open access
Keyword:distributed power generation
power distribution control
power generation control
power system dynamic stability
power system restoration
islanded microgrids
droop control
d-q frame
distributed generators
fictitious impedance
microgrid dynamics
microgrid stability
restoration control
frequency amplitude
voltage amplitude
required communications
transient guarantee
Description
Summary:The droop control method is usually selected when several distributed generators (DGs) are connected in parallel forming an islanded microgrid. This is because of the advantages it offers such as flexibility, absence of critical communications etc. Besides, several studies add a fictitious impedance to improve the performance of the original droop method. However, only a few studies deal with the design of this fictitious impedance, which is necessary to ensure an improvement in the dynamics and stability of the microgrid. In addition, these studies do not consider load variations for the design of the fictitious impedance, which is a habitual event in these systems. On the other hand, some studies propose a restoration control to bring the frequency and voltage amplitude of the microgrid to their nominal values. However, these do not deal with the design of the dynamics of this control to maintain a good transient and to ensure the stable performance of the microgrid. This study proposes the design of a fictitious impedance that ensures the stable operation of an experimental microgrid without power oscillations during load jumps and throughout its entire load range. This study also proposes a new restoration control that allows to take into account the possible inertias, delays etc. of the DGs and reduces the bandwidth of the required communications. Moreover, the proposed restoration control is properly designed to guarantee a good transient and the satisfactory performance of the microgrid. Experimental results confirm the validity of the proposed controls.