Arctan Power–Frequency Droop for Improved Microgrid Stability

Author

Rowe, Christopher N. ; Summers, T.J. ; Betz, R.E. ; Cornforth, David J. ; Moore, Timothy G.

Author_Institution

Sch. of Electr. Eng. & Comput. Sci., Univ. of Newcastle, Newcastle, NSW, Australia

Volume

28

Issue

8

fYear

2013

fDate

Aug. 2013

Firstpage

3747

Lastpage

3759

Abstract

The term microgrid is usually reserved for a modest sized, local distributed generation network that will largely operate standalone (i.e., without a grid connection.) The most common power flow control method utilized in a standalone microgrid is a technique known as power-frequency droop. This paper introduces the concept of utilizing an arctan function for the power-frequency droop profile. The use of this arctan function improves the small signal stability of the two-inverter microgrid, provides natural frequency bounding, and is flexible in its application. SABER simulations are performed to obtain the operating points about which the system is linearized for the stability analysis. Experimental results obtained from a dSPACE-controlled, low-voltage, two-inverter hardware system are presented to verify the theoretical and simulation results.

Keywords

distributed power generation; frequency control; invertors; power generation control; power system stability; SABER simulations; arctan power-frequency droop; dSPACE-controlled; local distributed generation network; microgrid stability; natural frequency bounding; power flow control method; small signal stability; two-inverter hardware system; two-inverter microgrid; Frequency control; Generators; Inverters; Power system stability; Reactive power; Stability analysis; Distributed control; distributed generation (DG); microgrids; power frequency droop; power sharing stability;

fLanguage

English

Journal_Title

Power Electronics, IEEE Transactions on

Publisher

ieee

ISSN

0885-8993

Type

jour

DOI

10.1109/TPEL.2012.2230190

Filename

6362236