Powersystem dynamic voltage stability affected by open‐loop modal coupling between DFIG‐based wind farms and IM loads

Power system voltage stability can be significantly affected by load dynamic characteristics. This study examines the impacts of dynamic interaction between doubly fed induction generator (DFIG)‐based wind farms and induction motor (IM) loads on system dynamic voltage stability. It is revealed that...

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Bibliographic Details
Published in:Journal of engineering (Stevenage, England) England), 2019-03, Vol.2019 (16), p.2514-2519
Main Authors: Su, Guoyun, Xu, Long, Du, Wenjuan, Chen, Chen, Ji, Yining, Wang, Haifeng
Format: Article
Language:English
Subjects:
aforementioned dynamic interaction
asynchronous generators
closed loop systems
closed‐loop interconnected model
damping
DFIG‐based wind farm
doubly fed induction generator‐based wind farms
dynamic voltage instability issues
IM load model
IM loads
IM oscillation mode
IMOM
induction motor loads
induction motors
load dynamic characteristics
modified WSCC 9‐bus system
open‐loop modal coupling
open‐loop subsystems
oscillations
power system dynamic voltage stability
power system stability
power system voltage stability
recovery response
system voltage instability
voltage‐source converter control loop
wind power plants
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Summary:Power system voltage stability can be significantly affected by load dynamic characteristics. This study examines the impacts of dynamic interaction between doubly fed induction generator (DFIG)‐based wind farms and induction motor (IM) loads on system dynamic voltage stability. It is revealed that the IM load model exhibits a recovery response which is accompanied by an IM oscillation mode (IMOM). The IMOM is first demonstrated to be closely related to system voltage stability. Moreover, a closed‐loop interconnected model is established, which consists of the following two open‐loop subsystems: DFIG; the rest of power system with IM loads. Generally, due to the fast response of the voltage‐source converter control loop, the dynamic interaction between the two open‐loop subsystems is weak. However, it is discovered that under a special condition named as open‐loop modal coupling, the aforementioned dynamic interaction will become tremendous. As a consequence, the damping of IMOM may be degraded substantially which can cause system voltage instability. Therefore, the mechanism of dynamic voltage instability issues is investigated from the perspective of modal coupling. A modified Western Systems Coordinating Council (WSCC) 9‐bus system integrated with a DFIG‐based wind farm is adopted to demonstrate and validate the above conclusions.
ISSN:2051-3305
2051-3305
DOI:10.1049/joe.2018.8579