Publications Internationales
Permanent URI for this collectionhttps://dspace.univ-boumerdes.dz/handle/123456789/13
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Item Energy Management and Control of a Hybrid Water Pumping System with Storage(Pléiades Publishing, 2017) Lazizi, Aldjia; Kesraoui, Mohamed; Achour, Djalloul; Chaib, AhmedThis paper aims to define a control and management strategy for water pumping system which would be powered by a hybrid PV/diesel generator system with battery storage. The particularity of the proposed power management method is to ensure the water volume in need and to maximize the use of PV generator while limiting the use of the diesel generator. In order to capture the maximum power from PV generator, a fuzzy logic maximum power point tracking controller is applied. On the other hand, a PI regulator is used with a boost converter in order to adapt the voltage of the battery bank to the DC bus. The water flow of the pump is also controlled. The developed power management and control strategy has been implemented using SIMPOWER toolbox in Matlab/Simulink. The obtained satisfying simulation results prove the efficiency of the proposed solution that assures continuous supply of water and electricityItem Fuzzy logic MPPT control for a solar PV module applied to water pumping(Inder Science Publisher, 2016) Lazizi, Aldjia; Kesraoui, Mohamed; Chaib, AhmedIn this paper, the fuzzy logic control for maximum power point tracking (MPPT) of a solar photovoltaic (PV) module in water pumping application is presented. A PV system including a solar module, a DC/DC boost converter, a fuzzy MPP tracker and a resistive load is modelled and simulated for various atmospheric conditions. The P-V and I-V characteristics are first obtained for various values of solar irradiation and temperature. Also, the increased efficiency of the photovoltaic system using MPPT is computed and plotted. The fuzzy control method is compared with the perturb and observe (P&O) method in one hand and with an improved P&O technique using artificial neural network (ANN) in the other. The fuzzy MPP tracker is then applied to the water pumping system composed of a solar panel, DC/DC boost converter, DC/AC inverter, induction motor and centrifugal pumpItem Fuzzy Logic Maximum Power Point Tracking Control for A Solar PV Module(2020) Lazizi, Aldjia; Kesraoui, Mohamed; Chaib, AhmedIn this paper, the fuzzy logic control for Maximum Power Point Tracking (MPPT) of a solar photovoltaic is presented. A photovoltaic system including a solar module, a DC/DC boost converter, a fuzzy MPP Tracker and a resistive load is modeled and simulated for various atmospheric conditions. The P-V characteristics are first obtained for various values of solar irradiation and temperature. Then the increased efficiency of the photovoltaic system using MPPT is computed and plotted. The fuzzy control method is compared with the Perturb/observe (P&O) method in one hand and with an Improved P&O technique using Artificial Neural Network (ANN) in the other hand.Item Complex systems modeling and faults detection, using neural networks and genetic algorithms(2015) Beddek, Karim; Kesraoui, MohamedItem Signal-Based sensor fault detection and isolation for PMSG in wind energy conversion systems(IEEE, 2017) Beddek, Karim; Merabet, Adel; Kesraoui, Mohamed; Tanvir, Aman A.; Beguenane, RachidItem Optimization of the artificial neural networks structure for filtering applications in wind energy conversion system(2015) Beddek, Karim; Kesraoui, Mohamed; Merabet, AdelItem Intelligent detection without modeling of behavior unusual by fuzzy logic(Springer, 2017) Chebi, Hocine; Acheli, Dalila; Kesraoui, MohamedItem Grid voltage local regulation by a doubly fed induction generator–based wind turbine(Sage journals, 2017) Kesraoui, Mohamed; Chaib, Ahmed; Bendaoui, Boujemaa; Achour, DjalloulVoltage regulation at point of common coupling using a doubly fed induction generator–based wind energy conversion system is achieved through reactive power control. Wind energy conversion system produces reactive power when the voltage is less than grid nominal voltage and it consumes it in the opposite case. In this article, a method to achieve this goal is proposed. It consists of controlling the reference value of the vector control system in order to affect the wind energy conversion system reactive power output. Two situations have been simulated. Sudden voltage increase and decrease were applied to the control system. Satisfying results have been obtained since the voltage at point of common coupling has been restored back to its initial valueItem Control of a Solar PV/wind Hybrid Energy System(Elsevier, 2016) Chaib, Ahmed; Achour, Djalloul; Kesraoui, MohamedA serious disadvantage of coupling a solar PV and wind energies of a hybrid system into the main DC bus is the compatibility of the voltage. In fact the PV system response is faster than the wind system one. This can affect negatively on the whole hybrid system response especially in case of variable loads switching. In this paper a hybrid energy system consisting of two sources: wind turbine generator and photovoltaic solar, without energy storage is modeled and simulated using MATLAB/SIMULINK. Management of the obtained power is achieved through two adaptor switches in the DC output of both sources. Each subsystem switch is controlled in order to supply either a dump load or the consumers’ loads via an inverter. The objective is to obtain an acceptable (compromise) system response and to make it more compatible. A control strategy of those two switches is proposed to adapt the inputs of the sources to the output of the DC bus. Satisfying results have been obtained in terms of voltage response stability, precision and global compatibility achievementItem Using a DFIG-based wind farm for grid node reactive power compensation(Inderscience Enterprises Ltd, 2013) Kesraoui, Mohamed; Chaib, Ahmed; Madri, Abdullah; Hammani, BilalGrid nodes voltages are not allowed to deviate excessively from nominal value. Appropriate measures should be taken to prevent such a deviation. The voltage difference between two nodes is strongly affected by reactive power flow. In contrast to frequency control, node voltage control must be achieved locally. This article investigates the use of a wind farm based on a doubly fed induction generators (DFIG) for reactive power compensation of a grid node. A wind speed variation sample is applied to the model of a wind power unit. The power flow between the stator of the DFIG-based wind power unit and the grid is controlled by using the decoupled active and reactive power vector control method. The limits or capacity of the stator and power converters to consume or provide reactive power are discussed. SIMULINK software has been used for the simulation of the system