Integrated Pq Enhancement System For Industrial And Commercial Grids Using Advanced Power Oscillation Mitigation Techniques
Keywords:
Solar photovoltaic (PV), Battery energy storage system (BESS), Power quality improvement, Power oscillations mitigation, Voltage regulation, Harmonic distortion reductiony.Abstract
The increasing penetration of solar power in commercial and industrial facilities poses significant challenges to power quality due to intermittency, voltage fluctuations, and power oscillations. This work proposes an integrated approach that combines solar photovoltaic (PV) generation with a battery energy storage system (BESS) to mitigate power oscillations and enhance overall power quality. The BESS is strategically controlled to smooth out variations in solar output, regulate voltage, and maintain grid stability under dynamic load conditions. Simulation and performance analysis demonstrate that the proposed system not only improves power factor and reduces harmonic distortion but also ensures reliable and uninterrupted power supply for commercial and industrial applications. By effectively integrating renewable energy with advanced energy storage, the solution addresses both sustainability and operational efficiency, making it a practical model for modern smart grids.
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References
Ray, P., Ray, P. K., & Panda, G. (2024). Power Quality and Reliability Improvement of Distribution System by Control of PV and Battery Integrated DSTATCOM. In ISSETA 2024 (Lecture Notes in Electrical Engineering,vol. 1254). Presented an integrated PV–BESS with DSTATCOM approach that dynamically mitigates harmonics, voltage disturbances, and DC-link fluctuations under load and solar variability.
[2] Wang, T., O'Neill, D., & Kamath, H. (2014). Dynamic Control and Optimization of Distributed Energy Resources in a Microgrid. This work employs a distributed optimization algorithm for a commercial microgrid with PV, BESS, EV charging, and curtailable loads, demonstrating real-time adaptive control.
[3] Weitemeyer, S., Kleinhans, D., Vogt, T., & Agert, C. (2014). Integration of Renewable Energy Sources in Future Power Systems: The Role of Storage. Using long-term solar–wind data, this modeling study highlights the necessity and sizing of storage systems for high renewable penetration scenarios.
[4] Barzegkar-Ntovom, G. A., Chatzigeorgiou, N. G., Nousdilis, A. I., et al. (2019). Assessing the viability of Battery Energy Storage Systems coupled with Photovoltaics under a pure self-consumption scheme. Evaluates techno-economic viability of PV-BESS for buildings, focusing on self-consumption policies without grid feed-in incentives.
[5] Vykhodtsev, A. V., Jang, D., Wang, Q., Zareipour, H., & Rosehart, W. D. (2021). A Review of Lithium-Ion Battery Models in Techno-economic Analyses of Power Systems. Reviews advanced modeling techniques for grid-scale BESS and their impact on economic and technical predictions.
[6] Subramaniam, U., Vavilapalli, S., Padmanaban, S., et al. (2020). A Hybrid PV-Battery System for ON-Grid and OFF-Grid Applications—Controller-In-Loop Simulation Validation. Describes a hybrid PV-battery system with control validation via controller-in-loop simulation for different operating modes.
[7] Şahin, M. E., & Blaabjerg, F. (2020). A Hybrid PV-Battery/Supercapacitor System and a Basic Active Power Control Proposal in MATLAB/Simulink. Proposes and simulates a hybrid energy storage system combining batteries and supercapacitors to manage active power control in PV installations.
[8] Babu, T. S., Vasudevan, K. R., Ramachandaramurthy, V. K., et al. (2020). A comprehensive review of hybrid energy storage systems: Converter topologies, control strategies and future prospects. An in-depth review of hybrid storage integration for renewable systems, including control schemes relevant to power quality.
[9] Chen, L. B., & Manohar, T. G. (2023). Control Strategies for Enhancing Power Quality with Unified Power Quality Conditioner in a Solar-PV Integrated Utility System. Presents adaptive UPQC control algorithms to actively compensate for PV-induced power quality issues.
[10] Faisal, M., Hannan, M. A., Ker, P. J., Hussain, A., Mansor, M. B., & Blaabjerg, F. (2018). Review of energy storage system technologies in microgrid applications: Issues and challenges. Offers a comprehensive overview of ESS roles in microgrids and their functions in enhancing power quality and stability.
