Improvement of direct torque control applied to doubly fed induction motor under variable speed

Aroussi, Hala Alami; Ziani, Elmostafa; Bouderbala, Manale; Bossoufi, Badre

doi:10.11591/ijpeds.v11.i1.pp97-106

Cited by 13 publications

(7 citation statements)

References 17 publications

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“…The Sliding-Backstepping Mode controller is composed of two parts: the first "u " generated by the sliding mode control and the second "u " generated by the Backstepping control [45], [46], [47].…”

Section: Generation Of the Global Control By The Sliding-backstepping...mentioning

confidence: 99%

Robust Sliding-Backstepping Mode Control of a wind system based on the DFIG Generator

Echiheb

Ihedrane

Bossoufi

et al. 2022

Preprint

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This paper presents a new contribution in the field of the optimization of the techniques of control of the wind systems, and the improvement of the quality of energy produced in the grid. The use of the Sliding Mode control technique gives quite interesting results, but its major drawback lies in the phenomenon of chattering (oscillations) which reduces the precision of the system. we propose in this work a solution to cancel this chattering phenomenon, by the implication of the adaptive Backstepping technique to control the powers of the double-fed asynchronous generator (DFIG) connected to the electrical network by two converters (network side and side machine) in the nominal part of the sliding mode model. This hybrid technique will correct errors of precision and stability and the performance of the wind system obtained in terms of efficiency, active and reactive power are very important. First, a review of the wind system was presented. Then, an exhaustive explanation of the Backstepping technique based on Lyapunov stability and optimization method has been reported. Subsequently, a validation on the Matlab & Simulink environment was carried out to test the performance and robustness of the proposed model. The results obtained from this work either by follow-up or robustness tests show a great improvement in terms of performance compared to other control techniques.

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Section: Generation Of the Global Control By The Sliding-backstepping...mentioning

confidence: 99%

Robust Sliding-Backstepping Mode Control of a wind system based on the DFIG Generator

Echiheb

Ihedrane

Bossoufi

et al. 2022

Preprint

Self Cite

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“…The advantages of SMC control are significant and multiple, a better precision, a very fast response time low and in particular robustness [10]- [22]. The SMC control is a robust method that has the strength to keep the uncertain systems performance, in various theorical and industrial applications, stable.…”

Section: Sliding Mode Control Strategymentioning

confidence: 99%

Sliding mode control design of wind power generation system based on permanent magnet synchronous generator

Laabidine

Errarhout

Bakkali

et al. 2021

IJPEDS

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This paper aims to implement a new contribution for sliding mode control (SMC) of permanent magnet synchronous generator (PMSG) for wind systems conversion with track the maximum power point tracking (MPPT) power. The SMC is a very popular approach due to its robustness in dealing with the non-linear electrical power systems. In this work, the application of the SMC control is by using the non lineare model of the PMSG. The objective of this work is to control stator active and stator reactive power, and the voltage-frequency for a better injection into the network. The results obtained show better robustness.

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“…Maximization of power control without speed control. while the variation of the wind speed in steady state is low compared to the electrical time constants of the system, we assume that the speed of rotation of the DFIG is fixed and neglecting the effect of the viscous torque f, the dynamic equation of the turbine becomes (12); from (12) we obtain the static equation describing the stationary state of the turbine (13); The reference electromagnetic torque is determined from an estimate of the aerodynamic torque given by (14),we obtain equation (15); The orientation angle of the blades β is assumed to be constant and the estimated speed of the turbine is calculated from the mechanical speed ( 16); The estimated wind speed is given by equation ( 17);on the Base of the previous equations, we can then write the equation of the reference electromagnetic couple (18). .…”

Section: Wind-turbine Modelmentioning

confidence: 99%

Improvement of Sliding Mode Power Control for WECS based on DFIG-Generator

Majout

Abrahmi

Ihedrane

et al. 2020

Wseas Transactions on Computer Research

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In this work, we are developing a new strategy for controlling wind systems based on the DFIG Generator. The SMC sliding mode technique is based on the principle of Lyapunov stability in order to make a nonlinear system close to linearity. The use of such a technique with an improvement in regulators to eliminate the Chattering phenomenon shows a great improvement in the performance of wind systems. which is based on performance estimators to improve the quality of the system. The energy quality at the output of the wind system will be injected into the distribution network according to international standards. The proposed model is validated on the Matlab & Simulink environment to test trajectory tracking and robustness.

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Improvement of direct torque control applied to doubly fed induction motor under variable speed

Cited by 13 publications

References 17 publications

Robust Sliding-Backstepping Mode Control of a wind system based on the DFIG Generator

Robust Sliding-Backstepping Mode Control of a wind system based on the DFIG Generator

Sliding mode control design of wind power generation system based on permanent magnet synchronous generator

Improvement of Sliding Mode Power Control for WECS based on DFIG-Generator

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