Your search keyword '"Bouchafaa, Farid"' showing total 2 results

1. Adaptive Fuzzy Logic-Based Control and Management of Photovoltaic Systems with Battery Storage.

Author

Assem, Houria, Azib, Toufik, Bouchafaa, Farid, Laarouci, Cherif, Belhaouas, Nasreddine, and Hadj Arab, Amar

Subjects

ADAPTIVE fuzzy control, RENEWABLE energy sources, BATTERY storage plants, DISTRIBUTED power generation, BATTERY management systems, REACTIVE power

Abstract

Renewable energy sources (RESs) such as solar photovoltaic (PV) systems are increasingly used as distributed generation for replacing the conventional energy. At the same time, energy storage systems like battery (BAT) must be applied for maintaining the balance between fluctuating energy production and load consumption. BAT's state of charge (SOC) should be maintained within their design limits unaffected by RES intermittency and/or load power variations. This necessitates advanced power control and management methodologies for overcoming challenging conditions. This paper discusses and evaluates an optimal DC bus voltage regulation approach: an intelligent controller using an adaptive fuzzy logic controller (FLC) and a novel supervisory power management strategy for PV systems with BAT. The objectives are to keep a stable power flow in the system and guarantee the continuity of service by ensuring that the system components do not exceed their limits. In this manner, the DC bus voltage regulation of the PV/BAT system can be improved in comparison with conventional regulation. Therefore, the most important contributions of this work are as follows. (1) Development of comprehensive and modular novel energy management system (EMS): its originality is related to the inclusion of the control system limits with faster SOC balancing and smaller DC bus voltage fluctuation. (2) Providing a simple power flow management implementation that considers the optimal energy flow between PV system, BAT system, and load: a balance between minimal energy flow in the connecting line and the least requirements of BAT capacity is kept, reducing component constraints with a very straightforward structure. (3) Furthermore, FLC offers high robustness and smooth performances. FLC is added to the control strategy design requirements to reduce DC bus voltage deviation. (4) Real-time simulation/experimentation-based complete cases utilizing Matlab/Simulink and DSpace are illustrated to testify the effectiveness of the proposed FLC and EMS. [ABSTRACT FROM AUTHOR]

Published

2023

2. Limits control and energy saturation management for DC bus regulation in photovoltaic systems with battery storage.

Author

Assem, Houria, Azib, Toufik, Bouchafaa, Farid, Hadj Arab, Amar, and Laarouci, Cherif

Subjects

*ELECTRIC motor buses, *ENERGY management, *PHOTOVOLTAIC power generation, *BATTERY storage plants, *MICROGRIDS, *POWER resources

Abstract

• Typical DC microgrid configuration uses two operation modes: normal and saturated. • This design problem implies a large-scale of photovoltaic-battery system applications. • Saturation management strategy involves dissipation system and regenerative break. • Power balance control ensures the energy distribution available from sources to load. • The control includes two methods: maximum power point tracking and power load tracking. Because of the considerable fluctuations of the power generation and load in Photovoltaic (PV) - Battery (BAT) systems, power management strategies become indispensable since BAT is needed to maintain the generation/load balance, and to regulate the DC bus. Indeed, energy management strategies must take into account the limits of the system, i.e. the nominal PV/BAT power rating and the state of charge (SOC) of BAT. However, the actual use might be different from the intended one, forcing the system to attain its limits. This paper is mainly focused on the limits control and energy saturation management applying to a sample standalone DC micro grid. It consists to share accurately the variable power loads among sources according to their ratings, including the regenerative breaking in minimum SOC'BAT case and the full supply of power load demand in maximum SOC'BAT case. Furthermore, the DC bus voltage is regulated to its predefined level, as a design parameter. The proposed control algorithms are detailed, and the system design during overstress and nominal conditions is given. The main advantage of this algorithm is its simplicity. The efficiency of the control strategy for energy saturation management is verified and analyzed through simulation/experimental system using Matlab/Simulink and DSpace. The results obtained show that the proposed technique can intelligently manage the energy flows and thus ensure that the system operates correctly and safely in the different modes: normal mode and saturated mode. [ABSTRACT FROM AUTHOR]

Published

2020