China develops tech to detect module faults in all weather and lights

Described in the paper detect module faults for silicon solar panels under all-day irradiation, which was recently published in Applied Optics, the novel technique consists of combining software that applies a modulated electric current to the PV panels and an indium-gallium-arsenide (InGaAs) photodiode detector that takes a sequence of images of the panels.

China develops tech to detect module faults in all weather and lights

Scientists at the Nanjing University of Science and Technology, in China, have developed a PV panel defect detection system that is claimed to work under any lighting conditions and in all weather.

Described in the paper module faults detection for silicon solar panels under all-day irradiation, which was recently published in Applied Optics, the novel technique consists of combining software that applies a modulated electric current to the PV panels and an indium-gallium-arsenide (InGaAs) photodiode detector that takes a sequence of images of the panels.

“Today’s defect detection systems can only be used to find defects at night or on solar panel modules that have been removed and moved inside or into a shaded environment,” researcher Yunsheng Qian stated.

Furthermore, the system includes a filter that is able to limit the detected wavelengths detected to around 1,150nm and to remove some of the stray sunlight from the images. “Using these image data as data sources, a defect display algorithm model is designed,” the researchers explained.

“The very fast imaging speed allows more images to be collected so that a greater number of changes between images can be distinguished,” said Sheng Wu, the paper’s main author. “The key development was a new algorithm that distinguishes the modulated and unmodulated parts of the image sequence and then magnifies this difference.”

The technique was tested on several mono and polycrystalline panels and the Chinese group claims it was able to detect faults on modules with irradiances from 0 to 1,300 W/m2, which it said equates to light conditions ranging from complete darkness to full sunlight. “The results show that this algorithm can reduce background interference in an effective way and improve the contrast of defects displayed under high irradiance.”

Looking forward, the research team is planning to develop software to reduce digital noise and improve image quality, so that the detector can collect image changes more accurately. The academics also want to see if artificial intelligence could be applied to the acquired images to automatically identify the types of defects, and further streamline the inspection process.

Originally published at Pv-magazine-Australia