Is hydrophobic coating on glass equally efficient in reducing % soiling loss of solar PVs in clean and polluted environments?

• Published in: Solar energy Vol. 265; p. 112120
• Main Authors: Ratnaparkhi, Aniket, Dave, Drashti, Meena, Rohit, Rastogi, Neeraj, Bergin, Mike, Ghoroi, Chinmay
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 15.11.2023
• Subjects: Dust composition; Field study; Hydrophobic coating; Particle size-resolved soiling; Preferential accumulation; Soiling loss; Soiling loss; Hydrophobic coating; Preferential accumulation; Particle size-resolved soiling; Dust composition; Field study
• ISSN: 0038-092X; 1471-1257
• DOI: 10.1016/j.solener.2023.112120

[Display omitted] •Preferentially 5 to 20 µm particles dominate mass loading on hydrophobic coated glass.•Particles between 15 to 25 µm dominate mass loading on uncoated glass.•Fine fraction (3 to 10 µm) contributes to ∼50% of total soiling loss for coated glass.•For uncoated glass, fine fraction only contributes to ∼27% of total soiling loss.•No significant difference in the mineralogy of the dust samples in ∼210 km2 area. Hydrophobic-coated glass (CS) on PV surfaces is known to reduce particulate matter (PM) accumulation. However, there is no comparative study on the % reduction in soiling loss (% RSL) on CS with respect to uncoated glass (UCS) for clean and polluted environments (higher atmospheric PM). The present field study (∼210 km2 in Gujarat, Western India) focuses on the evaluation of particle-size distribution of PM on CS and UCS, quantification of size-resolved soiling due to PM accumulation on CS and UCS, and comparison of % RSL of CS in cleaner and polluted environments. The findings show that 3 to 10 µm particles contribute to ∼21% and ∼12% of the total mass accumulated on CS and UCS, respectively. The observations are also validated using the theoretical adhesion model and critical rebounding velocity. Moreover, this particle-size fraction contributes to ∼50% of the total soiling loss for CS against only ∼27% soiling loss for UCS. Therefore, CS surfaces under polluted environments are expected to have a higher % of finer particle-size fraction in accumulated PM, which contributes significantly to the total soiling loss of CS and reduces the difference in % soiling loss between CS and UCS. Although CS reduces PM accumulation in both clean and polluted regions, the % RSL using CS is comparatively less in a polluted environment. The observations from the present study provide greater insight into the soiling aspect of solar PVs and have significant economic implications in deploying PV surfaces with hydrophobic coated glass.