PV modules serve as the core units of a PV plant, converting solar radiation into electrical energy. When a module’s conversion efficiency is compromised by abnormalities, less solar radiation is transformed into electricity. According to the principle of energy conservation, the lost energy is converted into excess heat, resulting in thermal defects. In other words, thermal defects directly affect a PV system’s power generation. Drawing from extensive practical experience and deep expertise in PV modules, thermal defects can be classified into twelve distinct types based on their causes and corresponding treatment methods.

The table above presents estimated impacts of thermal defects on PV module power output, based on relevant research. For example, hotspots can reduce module power by approximately 0.83% to 15.47%, while Potential-Induced Degradation (PID) may lead to losses ranging from 30% to 70%, depending on severity.

The above calculation does not account for the series and parallel connection effects of PV modules, making it a relatively conservative estimate of power generation losses. In reality, any abnormal module can influence the performance of others within the same series. For example, a module with broken glass may not only develop hotspots but also reduce the current of the entire string. Additionally, insulation resistance issues can lead to inverter shutdowns, further amplifying power generation losses. Over time, these effects compound, significantly impacting overall system efficiency. Therefore, early detection and timely intervention in thermal defects are essential to minimizing power losses and ensuring stable system operation.