Your search keyword '"DÖŞOĞLU, M. Kenan"' showing total 2 results

1. Decoupled power-based sliding mode control modeling enhancement for dynamic stability in doubly-fed induction generator-based wind turbines.

Author

Döşoğlu, M. Kenan

Subjects

*INDUCTION generators, *SLIDING mode control, *DYNAMIC stability, *WIND turbines, *ELECTROMOTIVE force, *DYNAMICAL systems

Abstract

• Decoupled power-based sliding mode control modeling strategy was developed for uncertain parameters and chattering problems in DFIG. • The rotor electromotive force model was developed to provide dynamic stability in DFIG. • The stator electromotive force model was developed to improve the performance of the simulation study. • The developed models were examined via balanced and unbalanced fault analyses. Low-voltage ride through (LVRT) capability is the principal method used to counteract voltage dips and over-current, which are caused by various balanced and unbalanced faults. However, in providing LVRT capability during faults, oscillations that occur in parameter changes should be damped for a short time. In this study, a decoupled power-based sliding mode control (SMC) in doubly-fed induction generator (DFIG)-based wind turbines was developed in order to eliminate the oscillation problems that may occur during balanced and unbalanced faults. Besides, while the stator electromotive force model in DFIG is developed with the aim of improving simulation performance and enabling ease of calculation, the rotor electromotive force model is developed to dynamic stability in the system during various faults. The results obviously indicated that the proposed decoupled power-based SMC and stator-rotor electromotive force models enhanced the LVRT capability of the grid-code requirement and quickly restored dynamic stability to the system. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

2. Enhancement of new rotor resistance unit for doubly fed induction generator-based wind turbines.

Author

Döşoğlu, M. Kenan

Subjects

*INDUCTION generators, *WIND turbines, *ROTORS, *ELECTROMOTIVE force, *LOW voltage systems, *STATORS

Abstract

• A new rotor resistance unit was developed for low voltage ride through capability in a doubly fed induction generator. • Stator and rotor dynamic modeling were developed against symmetrical and symmetrical faults. • Electromotive force models are developed in stator and rotor circuits. • A comparison was made of symmetrical and symmetrical faults with and without proposed model. It is very important to obtain smooth power and limit over-currents in grid-connected doubly fed induction generator (DFIG)-based wind turbines. Therefore, the rotor resistance unit can be used for power and over-currents control in DFIG. However, it may be insufficient to reduce oscillations in large power systems. This study aims to develop a new rotor resistance unit for low voltage ride through (LVRT) capability in DFIG. Moreover, electromotive-force (emf) models have been also developed in the stator and rotor circuit. The stator emf model of the simulation study was developed in the DFIG for accuracy and speed, while the rotor emf model was developed for over-current occurring in transient situations. In using the new rotor resistance unit and the stator-rotor emf, it was observed that the system stabilized in a short time, and the oscillations formed by the balanced and unbalanced faults on the grid side were damped. [ABSTRACT FROM AUTHOR]

Published

2021