The rotor of doubly-fed induction generator (DFIG) is connected to the grid through converters and the active power can be regulated by controlling the converters. Thus DFIG can quickly response to frequency fluctuations with virtual inertial control, releasing kinetic energy stored in rotors. However, it must exit from frequency regulation mode when rotor speed decreases to the minimum allowable speed, limited by finite kinetic energy stored in rotor, and then its output power will drop rapidly, leading to a secondary frequency dip. This paper proposes a new method to alleviate the secondary dip where DFIG can exit smoothly so that sharp decrease in system frequency can be avoided. Compared to the traditional recovering strategy, sudden change in output power is avoided under this control, so the frequency changes smoothly at the cost of a comparatively wider recovering time scale. The influence of parameters is analyzed and methods of parameter determination are given accordingly. Simulation shows that the proposed strategy can efficiently reduce the secondary frequency dip.
[1]
Zhe Chen,et al.
Optimal control method for wind farm to support temporary primary frequency control with minimised wind energy cost
,
2015
.
[2]
J.M. Mauricio,et al.
Frequency Regulation Contribution Through Variable-Speed Wind Energy Conversion Systems
,
2009,
IEEE Transactions on Power Systems.
[3]
G. Joos,et al.
Short-term frequency support utilizing inertial response of DFIG wind turbines
,
2011,
2011 IEEE Power and Energy Society General Meeting.
[4]
Qiu Jia-ju.
Frequency Control Strategy of Variable-speed Constant-frequency Doubly-fed Induction Generator Wind Turbines
,
2009
.
[5]
P. M. Anderson,et al.
A low-order system frequency response model
,
1990
.