Model‐predictive control‐based hybrid optimized load frequency control of multi‐area power systems

It is distinguished that there should be a balance between power generation and load demand, thereby maintaining the frequency and tie‐line power of the multi‐source multi‐area interconnected power system (MS‐MA‐IPS) in a determined limit to safeguard the entire system from failure. Hence, load freq...

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Bibliographic Details
Published in:IET generation, transmission & distribution transmission & distribution, 2021-05, Vol.15 (9), p.1521-1537
Main Authors: MV, Mahendran, V, Vijayan
Format: Article
Language:English
Subjects:
Control of electric power systems
Frequency control
Optimisation techniques
Power system control
Power system management, operation and economics
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Summary:It is distinguished that there should be a balance between power generation and load demand, thereby maintaining the frequency and tie‐line power of the multi‐source multi‐area interconnected power system (MS‐MA‐IPS) in a determined limit to safeguard the entire system from failure. Hence, load frequency control (LFC) by adjusting the megawatt output of generators is applied, which has been considered as the most recent research work in this field. Under these circumstances, this paper intends to construct a dual‐mode‐switch‐controller‐based LFC in a multi‐area power system, which obviously considers the impact of incremental control action along with the system dynamic constraints such as capacitive energy storage, generation rate constraint, and governor with dead band. In order to achieve this effect, in this research work, the operations of the proposed controller of the MS‐MA‐IPS are based on the dual‐mode switch, and here, switching is carried out with respect to a threshold value ξ. Based on switching, the control varies between proportional–integral (PI) control and model‐predictive control. Moreover, in order to make the performance elegant, the proportional gain of the PI controller Kpg and the threshold of the switch ξ are optimally tuned by introducing a novel optimisation algorithm referred to as particle updated dragonfly algorithm, which is the conceptual hybridisation of the traditional dragonfly algorithm and particle swarm optimisation. Finally, the performance of the proposed model is evaluated by varying the control parameters such as Cg, TCD, Tr, and Trb to minimize the undesired deviations in power flows between control areas.
ISSN:1751-8687
1751-8695
DOI:10.1049/gtd2.12119