Fuente: Sustainability - Revista científica (MDPI) Sustainability, Vol. 18, Pages 5404: Comparative Experimental Assessment of Photovoltaic Panel Stability Under Moderate Freeze–Thaw Thermal Cycling
Sustainability doi: 10.3390/su18115404
Authors:
Răzvan-Andrei Polcovnicu
Sebastian-Valeriu Hudișteanu
Nicolae Țăranu
Dragoș Ungureanu
Marius Alexa
Iuliana Hudișteanu
Nelu-Cristian Cherecheș
Florin-Emilian Țurcanu
Cătălin Onuțu
Alexandru-Florin Mustiață

This study presents an experimental investigation on the electrical performance, durability, and sustainability of different types of photovoltaic panels subjected to controlled climatic conditions and simulated solar radiation. Four photovoltaic technologies were analyzed, including monocrystalline, polycrystalline, and two semi-flexible panels, to evaluate their behavior under thermal stress. The experimental methodology consisted of repeated freeze–thaw cycles conducted in a double climatic chamber, with temperatures varying between −18 °C and +5 °C. Each panel was subjected to up to 500 cycles designed to reproduce repeated freeze–thaw environmental conditions representative of moderate cold-climate operation. At predefined intervals, the electrical characteristics of the panels were assessed using a solar radiation simulator based on high-pressure mercury vapor lamps, ensuring controlled and repeatable irradiation conditions. The results indicate that all tested panels exhibited relatively stable open-circuit voltage and output current values throughout the investigated thermal cycling interval, with only minor fluctuations observed during the experimental measurements. No visible macroscopic structural degradation and no major variations in the monitored electrical parameters were identified during the investigated testing conditions. Semi-flexible panels demonstrated comparable behavior to rigid panels, highlighting their potential for applications requiring mechanical adaptability. From a sustainability perspective, the observed durability and performance stability contribute to extending the operational lifetime of photovoltaic systems, reducing maintenance needs and material replacement rates. The findings provide comparative experimental observations regarding the evolution of selected electrical parameters under repeated moderate freeze–thaw exposure conditions.