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access icon free Analysis and investigation on direct and cross coupling effect of small isolated and interconnected wind diesel power generating system

© The Institution of Engineering and Technology
Received 06/07/2016, Accepted 31/10/2016, Revised 26/09/2016, Published 04/11/2016

This study presents the analysed result of wind–diesel system with the consideration of real power-frequency control, reactive power-voltage control as well as cross-coupling between reactive power-frequency and real power-voltage control. The system under study uses synchronous generator (SG) for diesel generator and induction generator (IG) for wind generation systems. The mathematical model of the system with both direct and cross-coupling effect is derived to simulate the behaviour of the wind–diesel system. The classical control technique and eigenvalue, participation factor matrix is used to study the strength of the direct and cross-coupling effect, in the studied system. The simulated responses of the system under various types of disturbances are presented to show the cross-coupling effect in the wind–diesel system. System performances under interconnected mode of operation is also studied.

Inspec keywords: diesel-electric generators; synchronous generators; reactive power control; wind power plants; voltage control; asynchronous generators; power generation control; frequency control; diesel-electric power stations; matrix algebra

Other keywords: induction generator; participation factor matrix; SG; reactive power-voltage control; mathematical model; interconnected wind diesel power generating system; cross coupling effect; eigenvalue; small isolated wind diesel power generating system; direct coupling effect; synchronous generator; classical control technique; diesel generator; real power-voltage control; real power-frequency control; reactive power-frequency

Subjects: Wind power plants; Frequency control; Power and energy control; Asynchronous machines; Voltage control; Algebra; Algebra; Synchronous machines; Diesel power stations and plants; Control of electric power systems

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