Grid integration of PV power based on PHIL testing using different interface algorithms

Author

Craciun, Bogdan-Ionut ; Kerekes, Tamas ; Sera, Dezso ; Teodorescu, Remus ; Brandl, Ron ; Degner, T. ; Geibel, D. ; Hernandez, H.

Author_Institution

Dept. of Energy Technol., Aalborg Univ., Aalborg, Denmark

fYear

2013

fDate

10-13 Nov. 2013

Firstpage

5380

Lastpage

5385

Abstract

Photovoltaic (PV) power among all renewable energies had the most accelerated growth rate in terms of installed capacity in recent years. Transmission System Operators (TSOs) changed their perspective about PV power and started to include it into their planning and operation, imposing PV systems to be more active in grid support. Therefore, a better understanding and detailed analysis of the PV systems interaction with the grid is needed; hence power hardware in the loop (PHIL) testing involving PV power can be a solution to address the testing challenges. To test PV systems for grid code (GC) compliance and supply of ancillary services, first the grid has to be simulated using PHIL, but in order to achieve it, different interface algorithms (IA) had to be evaluated in terms of system stability and signal accuracy.

Keywords

photovoltaic power systems; power grids; GC; IA; PHIL testing; PV power grid integration; PV systems; TSOs; accelerated growth rate; ancillary service supply; grid code compliance; interface algorithms; photovoltaic power; power hardware in the loop testing; power system stability; renewable energy; signal accuracy; transmission system operators; Current measurement; Hardware; Impedance; Power system stability; Software; Stability analysis; Testing; DIM; ENTSO-E; HuT; IA; ITM; PHIL; PV power; grid integration;

fLanguage

English

Publisher

ieee

Conference_Titel

Industrial Electronics Society, IECON 2013 - 39th Annual Conference of the IEEE

Conference_Location

Vienna

ISSN

1553-572X

Type

conf

DOI

10.1109/IECON.2013.6700011

Filename

6700011