KHALED Benzaoui
بن زاوي خالد
khaled.benzaoui@univ-msila.dz
0658492529
- DEPARTEMENT OF: ELECTRICAL ENGINEERING
- Faculty of Technology
- Grade PHd
About Me
Location
Msila, Msila
Msila, ALGERIA
Code RFIDE- 1994-12-01 00:00:00
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KHALED Benzaoui birthday
- 2024-12-09
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2024-12-09
Real-Time HIL Implementation of Integrated Wind Turbine and DSIG System
Several approaches have been put out to capture wind energy and transform it into electrical energy. The modeling and control of a dual stator induction generator (DSIG) incorporated into a wind energy conversion system is the particular focus of this study. The controls on the generator side and the conversion system's output parameters must be adjusted to achieve the best possible power flow to the grid and guarantee peak system performance. Alternative machine control is popular for PI controllers. Creating PI gains is difficult in this situation because the rectifier powering the DSIG is simultaneously controlled with a phase angle change of thirty degrees. A nonlinear backstepping control approach is suggested to lessen this difficulty. This investigation's comparison analysis compares the effectiveness of the two control systems using a variety of simulated tests. In steady-state settings, the tracking performance of both controls is similar. However, the backstepping control performs better in a transient mode in terms of overshoot and response time. A thorough analysis and validation of the suggested control mechanism is performed using sophisticated simulations in the Plecs/RT BOX environment.
Citation
ABDERRAHMEN Bouguerra , Khaled benzaoui , SAMIR Zeghlache , ,(2024-12-09), Real-Time HIL Implementation of Integrated Wind Turbine and DSIG System,1st National Conference of Advanced Systems in Electrical Engineering (NCASEE'24),,University M'Hamed Bougara of Boumerdes, Algeria.
- 2024-11-24
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2024-11-24
HIL Implementation using DSIG in Wind Energy Conversion system
Several approaches have been put out to capture wind energy and transform it into electrical energy. The modeling and control of a dual stator induction generator (DSIG) incorporated into a wind energy conversion system is the particular focus of this study. The controls on the generator side and the conversion system's output parameters must be adjusted to achieve the best possible power flow to the grid and guarantee peak system performance. Alternative machine control is popular for PI controllers. Creating PI gains is difficult in this situation because the rectifier powering the DSIG is simultaneously controlled with a phase angle change of thirty degrees. A nonlinear backstepping control approach is suggested to lessen this difficulty. This investigation's comparison analysis compares the effectiveness of the two control systems using a variety of simulated tests. In steady-state settings, the tracking performance of both controls is similar. However, the backstepping control performs better in a transient mode in terms of overshoot and response time. A thorough analysis and validation of the suggested control mechanism is performed using sophisticated simulations in the Plecs/RT BOX environment.
Citation
ABDERRAHMEN Bouguerra , Khaled benzaoui , SAMIR Zeghlache , ,(2024-11-24), HIL Implementation using DSIG in Wind Energy Conversion system,The 2nd national conference on electronics,electrical engineering,telecommunications, and computer vision,Mila.Algeria
- 2024-11-17
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2024-11-17
HIL platform for Wind Turbine system based on DSIG controlled by backstepping
Several approaches have been put out to capture wind energy and transform it into electrical energy. The modeling and control of a dual stator induction generator (DSIG) incorporated into a wind energy conversion system is the particular focus of this study. The controls on the generator side and the conversion system's output parameters must be adjusted to achieve the best possible power flow to the grid and guarantee peak system performance. Alternative machine control is popular for PI controllers. Creating PI gains is difficult in this situation because the rectifier powering the DSIG is simultaneously controlled with a phase angle change of thirty degrees. A nonlinear backstepping control approach is suggested to lessen this difficulty. This investigation's comparison analysis compares the effectiveness of the two control systems using a variety of simulated tests. In steady-state settings, the tracking performance of both controls is similar. However, the backstepping control performs better in a transient mode in terms of overshoot and response time. A thorough analysis and validation of the suggested control mechanism is performed using sophisticated simulations in the Plecs/RT BOX environment.
Citation
ABDERRAHMEN Bouguerra , Khaled benzaoui , SAMIR Zeghlache , ,(2024-11-17), HIL platform for Wind Turbine system based on DSIG controlled by backstepping,8th national colloquium on inductics university-industry,M'sila.Algeria
- 2024-10-19
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2024-10-19
SABO optimization algorithm-based backstepping controller for DSIG within a wind turbine system
Tuning the PI and backstepping (BS) controllers is a critical issue for ensuring good tracking performance and stable operation of the wind turbine based on dual-stator induction generator (WT-DSIG) systems. However, no existing research has yet comprehensively tuned the control parameters. Therefore, this paper proposes an innovative tuning method using the subtraction-average-based optimizer (SABO) to ensure optimal PI and backstepping controller parameters tuning. The optimally tuned controllers-based field-oriented control (FOC) scheme is applied for a WT-DSIG system. This research aims to offer an easy and effective method for optimal tuning of the control parameters, which contributes to improving the control performance, hence the WT-DSIG system’s stability. The proposed method is superior to the existing techniques, as it uses the SABO, a metaheuristic stochastic algorithm, to simultaneously optimize the natural frequencies of the flux, speed, and current PI controllers and the backstepping controller’s gains. To assess the effectiveness of the proposed control approach, a hardware-in-the-loop (HIL) implementation is carried out using the PLECS/RT-Box real-time simulator. The HIL findings through comparative study further confirm the superiority of the optimally designed controllers over the conventional techniques, highlighting significant enhancements in dynamic, steady state, THD, and time-integral performance criteria, ISE, and IAE.
Citation
ABDERRAHMEN Bouguerra , Khaled benzaoui , SAMIR Zeghlache , , (2024-10-19), SABO optimization algorithm-based backstepping controller for DSIG within a wind turbine system, Electrical Engineering, Vol:2024, Issue:2024, pages:17, The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature 2024
- 2022
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2022
Field Oriented Control Technique of a Wind System based on a Dual Stator Induction Generator
The objective of this work is to remain constant of the DC bus, The dual stator induction generator (DSIG) supplies a variable load, in this study is to assess the suitability and performance of the control technique which is field oriented control technique (FOC) with PI regulator, allows to achieve the desired performance. The proposed control strategy is validated by simulation in Matlab/Simulink.
Citation
Khaled benzaoui , ,(2022), Field Oriented Control Technique of a Wind System based on a Dual Stator Induction Generator,The 2022 International Conference of Advenced Technology in Electronic and Electrical Engineering (ICATEEE),m'sila university-algeria
- 2022
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2022
Field Oriented Control Technique of a Wind System based on a Dual Stator Induction Generator
The objective of this work is to remain constant of the DC bus, The dual stator induction generator (DSIG) supplies a variable load, in this study is to assess the suitability and performance of the control techniques which is field oriented control technique (FOC) with PI regulator, allows to achieve the desired performance. The proposed control strategy is validated by simulation in Matlab/Simulink
Citation
Khaled benzaoui , ABDERRAHMEN Bouguerra , SAMIR Zeghlache , Mohammed boukhari , ayyoub.zeghlache@univ-msila.dz, ,(2022), Field Oriented Control Technique of a Wind System based on a Dual Stator Induction Generator,The 2022 InternationalThe 2022 International Conference of advanced Technology in Electronic and Electrical Engineering (ICATEEE),M'sila, Algeria
- 2022
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2022
Fault Tolerant Control of PMSM based on Improved Exponential ESO
In this work, a Fault-Tolerant Control (FTC) design is based on a novel reaching law sliding mode control (SMC) with an improved exponential extended state observer (ESO) for a 3-phase Permanent Magnet Synchronous Motor (PMSM) is proposed. Moreover, a direct field-oriented control based on ESO with a novel reaching law SMC is designed to achieve robust performance against parameter variations and external disturbances. The main goal of using an improved exponential ESO is to detect and reconstruct disturbances and faults. Furthermore, the stability of these observers and controllers is proved by using the Lyapunov stability theory.
Citation
AYYOUB Zeghlache , HEMZA Mekki , ALI Djerioui , Khaled benzaoui , Mohamed Fouad Benkhoris, ,(2022), Fault Tolerant Control of PMSM based on Improved Exponential ESO,the 2022 International Conference of advanced Technology in Electronic and Electrical Engineering (ICATEEE),M'sila University, Algeria
- 2021
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2021
Commande non linéaire robuste d'un systéme éolien basé sur une génératrice asynchrone double étoile
Wind energy is a source of energy that depends on the wind, is a kinetic energy of moving air masses around the globe, Wind energy is an indirect form of solar energy: the solar rays absorbed in the atmosphere lead to differences in temperature and pressure. The development of variable-speed wind technology and at constant frequency has today become a major area of interest in achieving a successful rapid and global migration towards this type of energy. The aim of this work is to implement robust nonlinear control techniques of a wind system based on a double star asynchronous generator, to independently control the active powers and reactive exchanged between the stator and the network. The objective is to assess the relevance and performance of advanced control techniques, such as (adaptive fuzzy control, Hybrid control, control by backstepping, control by sliding mode, etc. allows to achieve the desired performance. These nonlinear control techniques applied on this type of system ensuring convergence in finite time and robustness against parametric uncertainties and external disturbances, which is one of the main contributions of this work.
Citation
Khaled benzaoui , ,(2021), Commande non linéaire robuste d'un systéme éolien basé sur une génératrice asynchrone double étoile,journée Doctorale en Génie Electrique 2022 (JDGE'2022),m'sila-algeria