A Control Technique for Integration of DG Units to the Electrical Networks

This paper deals with a multiobjective control technique for integration of distributed generation (DG) resources to the electrical power network. The proposed strategy provides compensation for active, reactive, and harmonic load current components during connection of DG link to the grid. The dyna...

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Bibliographic Details
Published in:IEEE transactions on industrial electronics (1982) 2013-07, Vol.60 (7), p.2881-2893
Main Authors: Pouresmaeil, E., Miguel-Espinar, C., Massot-Campos, Miquel, Montesinos-Miracle, D., Gomis-Bellmunt, O.
Format: Article
Language:English
Subjects:
Active filters
Convertidors de corrent elèctric
Digital signal processor
distributed generation (DG)
Distributed generation of electric power
Energia elèctrica
Energies
Harmonic analysis
Load modeling
Mathematical model
Power electronics
Power harmonic filters
Reactive power
renewable energy sources
Tecnologia energètica
total harmonic distortion (THD)
Voltage control
voltage source converter (VSC)
Àrees temàtiques de la UPC
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Summary:This paper deals with a multiobjective control technique for integration of distributed generation (DG) resources to the electrical power network. The proposed strategy provides compensation for active, reactive, and harmonic load current components during connection of DG link to the grid. The dynamic model of the proposed system is first elaborated in the stationary reference frame and then transformed into the synchronous orthogonal reference frame. The transformed variables are used in control of the voltage source converter as the heart of the interfacing system between DG resources and utility grid. By setting an appropriate compensation current references from the sensed load currents in control circuit loop of DG, the active, reactive, and harmonic load current components will be compensated with fast dynamic response, thereby achieving sinusoidal grid currents in phase with load voltages, while required power of the load is more than the maximum injected power of the DG to the grid. In addition, the proposed control method of this paper does not need a phase-locked loop in control circuit and has fast dynamic response in providing active and reactive power components of the grid-connected loads. The effectiveness of the proposed control technique in DG application is demonstrated with injection of maximum available power from the DG to the grid, increased power factor of the utility grid, and reduced total harmonic distortion of grid current through simulation and experimental results under steady-state and dynamic operating conditions.
ISSN:0278-0046
1557-9948
DOI:10.1109/TIE.2012.2209616