Abstract
This paper proposes a grouped, reactive power optimization control strategy to maximize the active power output of a doubly-fed induction generator (DFIG) based on a large wind farm (WF). Optimization problems are formulated based on established grouped loss models and the reactive power limits of the wind turbines (WTs). The WTs in the WF are grouped to relieve computational burden. The particle swarm optimization (PSO) algorithm is applied to optimize the distribution of reactive power among groups, and a proportional control strategy is used to distribute the reactive power requirements in each group. Furthermore, the proposed control strategy optimizes the reactive power distribution between the stator and the grid side converter (GSC) in each WT. The proposed control strategy greatly reduces the number of variables for optimization, and increases the calculation speed of the algorithm. Thus, the control strategy can not only increase the active power output of the WF but also enable the WF to track the reactive power dispatching instruction of the power grid. A simulation of the DFIG WF is given to verify the effectiveness of the proposed control strategy at different wind speeds and reactive power references.
Highlights
This paper proposes a grouped reactive power optimization control strategy for large doubly-fed induction generator (DFIG) wind farm (WF), which is partly reported in PESA [21]
It divides the wind turbines (WTs) into several groups and uses the particle swarm optimization (PSO) algorithm to optimize the distribution of reactive power among groups
A simulated DFIG WF with two feeders was built on the MATLAB/Simulink
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. A novel active power dispatching strategy based on dynamic grouping of WTs is proposed to obtain smoother active power references in [16] This can enable WTs to track the dispatching instruction and alleviate the fatigue of WTs in order to achieve the reactive power requirements of the power grid and decrease the losses of the WF. This paper proposes a grouped reactive power optimization control strategy for large DFIG WFs, which is partly reported in PESA [21]. It divides the WTs into several groups and uses the PSO algorithm to optimize the distribution of reactive power among groups.
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