        TY  - JOUR
T1  - Modeling and Performance Analysis of Battery Energy Storage Incorporated Grid-Connected Photovoltaic Plants
TT  - Modeling and Performance Analysis of Battery Energy Storage Incorporated Grid-Connected Photovoltaic Plants
AU  - Çelik, Özgür
AU  - Kabadayi, Türker Aşkın
PY  - 2025
DA  - September
Y2  - 2025
DO  - 10.21605/cukurovaumfd.1745510
JF  - Çukurova Üniversitesi Mühendislik Fakültesi Dergisi
PB  - Çukurova Üniversitesi
WT  - DergiPark
SN  - 2757-9255
SP  - 569
EP  - 579
VL  - 40
IS  - 3
LA  - en
AB  - This study conducts a detailed performance comparison between two large-scale photovoltaic (PV) power plants, each with an installed capacity of 1 MW. One system follows a conventional PV configuration, while the other incorporates a battery energy storage system (BESS) for enhanced functionality. The BESS-integrated system employs a peak-shaving strategy, aiming to store excess energy generated beyond 1 MW during daytime hours. The primary goals are to extend the PV system’s energy supply into peak demand periods following sunset and to improve responsiveness to energy demand fluctuations. Both configurations were independently modeled using the same simulation environment, with a focus solely on technical performance, excluding economic considerations. Simulation results reveal that the BESS-enhanced system delivers an additional 153.18 MWh annually to the grid and achieves a 4.8% improvement in performance ratio. These findings highlight the technical benefits of BESS integration in PV systems, particularly its contribution to improving energy continuity. The study offers valuable insights for system designers, investors, and researchers regarding the implementation of BESS in solar power applications.
KW  - Photovoltaic System
KW  - Peak Shaving
KW  - Energy Storage
KW  - Battery
N2  - This study conducts a detailed performance comparison between two large-scale photovoltaic (PV) power plants, each with an installed capacity of 1 MW. One system follows a conventional PV configuration, while the other incorporates a battery energy storage system (BESS) for enhanced functionality. The BESS-integrated system employs a peak-shaving strategy, aiming to store excess energy generated beyond 1 MW during daytime hours. The primary goals are to extend the PV system’s energy supply into peak demand periods following sunset and to improve responsiveness to energy demand fluctuations. Both configurations were independently modeled using the same simulation environment, with a focus solely on technical performance, excluding economic considerations. Simulation results reveal that the BESS-enhanced system delivers an additional 153.18 MWh annually to the grid and achieves a 4.8% improvement in performance ratio. These findings highlight the technical benefits of BESS integration in PV systems, particularly its contribution to improving energy continuity. The study offers valuable insights for system designers, investors, and researchers regarding the implementation of BESS in solar power applications.
CR  - 1.	Çelik, Ö. (2023). Analysis of current limiting algorithm with anti-windup control for transient stability of grid-forming converters. Çukurova Üniversitesi Mühendislik Fakültesi Dergisi, 38(3), 671-681.
CR  - 2.	Erişti, H., Akdağli, A., Baldan, E. &amp; Sarı, A. (2025). Investigation of panel efficiency in photovoltaic systems under partial shading and different pollution conditions: An experimental study. Çukurova Üniversitesi Mühendislik Fakültesi Dergisi, 40(2), 301-311.
CR  - 3.	Çelik, Ö., Zor, K., Tan, A. &amp; Teke, A. (2022). A novel gene expression programming-based MPPT technique for PV micro-inverter applications under fast-changing atmospheric conditions. Solar Energy, 239, 268-282.
CR  - 4.	Çelik, Ö., Büyük, M. &amp; Tan, A. (2022). Mitigation of power oscillations for energy harvesting capability improvement of grid-connected renewable energy systems. Electric Power Systems Research, 213, 108756.
CR  - 5.	Çelik, Ö. (2025). An efficient control scheme for operational performance enhancement of vehicular fuel cell integrated power system. Journal of Power Sources, 625, 235660.
CR  - 6.	Inaolaji, A., Wu, X., Roychowdhury, R. &amp; Smith, R. (2024). Optimal allocation of battery energy storage systems for peak shaving and reliability enhancement in distribution systems. Journal of Energy Storage, 95, 112305.
CR  - 7.	Bozkurt, H., Çelik, Ö. &amp; Teke, A. (2024). Power quality enhancement in hybrid PV-BES system based on ANN-MPPT. Turkish Journal of Electrical Engineering and Computer Sciences, 32(5), 662-681.
CR  - 8.	Gandhi, O., Kumar, D.S., Rodríguez‑Gallegos, C.D. &amp; Srinivasan, D. (2020). Review of stability and reliability implications on power systems with high PV penetration: Part II – Potential solutions and the way forward. Renewable and Sustainable Energy Reviews, 132, 110018.
CR  - 9.	Okafor, C. E., Gbadamosi, S. L., Krishnamurthy, S., Ratshitanga, M. &amp; Moodley, P. (2025). Techno-economic analysis of battery storage technologies in distribution networks with integrated electric vehicles and solar PV systems. Energy Reports, 14, 579-599.
CR  - 10.	Sharma, D.D., Singh, S.N., Rajpurohit, B.S. &amp; Longatt, F.G. (2015). Critical load profile estimation for sizing of battery storage system. In Proceedings of the IEEE Power &amp; Energy Society General Meeting.
CR  - 11.	Li, H., Wang, L., Song, Y., Zhang, Z., Zhang, H., Du, A. &amp; He, X. (2023). Significance of current collectors for high-performance conventional lithium-ion batteries: A review. Advanced Functional Materials, 33(49), 2305515.
CR  - 12.	Rouholamini, M., Wang, C., Nehrir, H., Hu, X., Hu, Z., Aki, H., Zhao, B., Miao, Z. &amp; Strunz, K. (2022). A review of modeling, management, and applications of grid-connected Li-ion battery storage systems. IEEE Transactions on Smart Grid, 13(6), 4505-4524.
CR  - 13.	Hill, C.A., Such, M.C., Chen, D., Gonzalez, J. &amp; Grady, W.M. (2012). Battery energy storage for enabling integration of distributed solar power generation. IEEE Transactions on Smart Grid, 3(2), 850-857.
CR  - 14.	Rahimi, A., Zarghami, M., Vaziri, M. &amp; Vadhva, S. (2013). A simple and effective approach for peak load shaving using battery storage systems. North American Power Symposium (NAPS), 1-5.
CR  - 15.	Cervantes, J. &amp; Choobineh, F. (2018). Optimal sizing of a nonutility‑scale solar power system and its battery storage. Applied Energy, 216, 105-115.
CR  - 16.	Lange, C., Rueß, A., Nuß, A., Öchsner, R. &amp; März, M. (2020). Dimensioning battery energy storage systems for peak shaving based on a real-time control algorithm. Applied Energy, 280, 115993.
CR  - 17.	PVsyst SA, (c. 2022). PVsyst Tutorials V7 [User’s manual—Grid-connected systems].
UR  - https://doi.org/10.21605/cukurovaumfd.1745510
L1  - https://dergipark.org.tr/tr/download/article-file/5067612
ER  -