PV Integration in LV Networks and Capacity Analysis

Muftić Dedović, Maja; Avdaković, Samir; Memić, Adin

doi:10.37798/2024734698

Journal of Energy : Energija, Vol. 73. No. 4., 2024.

Original scientific paper

https://doi.org/10.37798/2024734698

PV Integration in LV Networks and Capacity Analysis

Maja Muftić Dedović orcid.org/0000-0003-4277-9553 ; Faculty of Electrical Engineering, University of Sarajevo, Sarajevo, Bosnia and Herzegovina *
Samir Avdaković ; Faculty of Electrical Engineering, University of Sarajevo, Sarajevo, Bosnia and Herzegovina
Adin Memić ; Faculty of Electrical Engineering, University of Sarajevo, Sarajevo, Bosnia and Herzegovina

* Corresponding author.

Full text: english pdf 990 Kb

page 3-11

downloads: 9

cite

APA 6th Edition

Muftić Dedović, M., Avdaković, S. & Memić, A. (2024). PV Integration in LV Networks and Capacity Analysis. Journal of Energy, 73. (4.), 3-11. https://doi.org/10.37798/2024734698

MLA 8th Edition

Muftić Dedović, Maja, et al. "PV Integration in LV Networks and Capacity Analysis." Journal of Energy, vol. 73., no. 4., 2024, pp. 3-11. https://doi.org/10.37798/2024734698. Accessed 5 Dec. 2025.

Chicago 17th Edition

Muftić Dedović, Maja, Samir Avdaković and Adin Memić. "PV Integration in LV Networks and Capacity Analysis." Journal of Energy 73., no. 4. (2024): 3-11. https://doi.org/10.37798/2024734698

Harvard

Muftić Dedović, M., Avdaković, S., and Memić, A. (2024). 'PV Integration in LV Networks and Capacity Analysis', Journal of Energy, 73.(4.), pp. 3-11. https://doi.org/10.37798/2024734698

Vancouver

Muftić Dedović M, Avdaković S, Memić A. PV Integration in LV Networks and Capacity Analysis. Journal of Energy [Internet]. 2024 [cited 2025 December 05];73.(4.):3-11. https://doi.org/10.37798/2024734698

IEEE

M. Muftić Dedović, S. Avdaković and A. Memić, "PV Integration in LV Networks and Capacity Analysis", Journal of Energy, vol.73., no. 4., pp. 3-11, 2024. [Online]. https://doi.org/10.37798/2024734698

Abstract

The increasing integration of photovoltaic (PV) systems in low-voltage (LV) networks presents challenges in violation of permitted voltage changes in the LV network and conductor and transformer capacity, which are critical for maintaining grid reliabi-lity and operational efficiency. This paper analyzes PV integration, focusing on voltage control, conductor capacity, and the importance of day-ahead PV generation and consumption for proactive grid ma-nagement. Using MATLAB, the LV network is modeled to assess vol-tage analysis and conductor capacity for PV capacities ranging from 3 kW to 8 kW per consumer. Predictions of day-ahead PV production are conducted using a feedforward neural network trained on meteo-rological data such as solar irradiance, temperature, and cloud cover. The predictive model enabled voltage drop simulations and capacity analysis under forecasted conditions. The results demonstrated that voltage levels remained within the permissible range (+5%, -10% of 400 V) for PV capacities up to 8 kW, ensuring operational reliabi-lity. The neural network-based predictions are closely aligned with modeled values, with minimal differences, validating the forecasting approach. Voltage variations increased with higher PV capacities, but conductor current levels consistently remained below thermal limits. Incremental PV capacity integration revealed the network’s ability to support distributed generation effectively but with limitati-ons at higher capacities. This research highlights the role of accurate forecasting and optimization in ensuring reliable renewable energy adoption.

Keywords

Distributed Energy Resources (DERs); Low-Voltage Networks; Neural Networks; Optimization; Prosumers; Voltage Analysis

Hrčak ID:

338948

URI

https://hrcak.srce.hr/338948

Publication date:

1.12.2024.

Visits: 25 *

Login and registration

Journal of Energy : Energija, Vol. 73. No. 4., 2024.

Abstract

Keywords

Hrčak ID:

URI

Publication date: